Methods of using monoclonal antibodies targeting epitopes of ASPH

ABSTRACT

Monoclonal antibodies (MAbs) targeting one or more specific epitopes of aspartyl (asparaginyl) β-hydroxylase (ASPH), including humanized, bi-specific, and other chimeric MAb variants, and fragments thereof (collectively ASPH epitope-specific MAbs, or simply ASPH MAbs), are disclosed. Methods of production, purification, and use of the ASPH epitope-specific MAbs, and compositions comprising them, as agents in therapeutic and diagnostic applications to interact with target molecules in cell-free samples, cell- and tissue-based assays, animal models, and in a subject are also disclosed. Other aspects of the invention relate to use of the molecules disclosed herein to diagnose, ameliorate, or treat cell proliferation disorders and related diseases.

CROSS REFERENCE TO RELATED APPLICATIONS

This is a divisional application that claims priority to and the benefit of U.S. Non-Provisional application Ser. No. 16/444,617, filed Jun. 18, 2019, and U.S. Provisional Application No. 62/686,107, filed Jun. 18, 2018, the entire contents of which are incorporated by reference in their entirety.

INCORPORATION-BY-REFERENCE OF A SEQUENCE LISTING

The Sequence Listing contained in the files “761_190_033_US_01_Sequence_Listing_ST25.txt”, created on 2020 Sep. 1, modified on 2020 Sep. 1, file size 44,370 bytes, containing SEQ ID NOS: 1-52, “761_190_026_US_Sequence_Listing_ST25.txt”, created on 2019 May 21, modified on 2019 May 21, file size 35,033 bytes, containing SEQ ID NOS: 1-30, and “761_190_025_US_Sequence_Listing_ST25.txt”, created on 2018 Jun. 17, modified on 2018 Jun. 17, file size 34,990 bytes, containing SEQ ID NOS: 1-30, are incorporated by reference in its entirety herein.

FIELD OF THE INVENTION

Monoclonal antibodies (MAbs) targeting one or more specific epitopes of aspartyl (asparaginyl) β-hydroxylase (ASPH), including humanized, bi-specific, and other chimeric MAb variants, and fragments thereof (collectively ASPH epitope-specific MAbs, or simply ASPH MAbs), are disclosed. Methods of production, purification, and use of the ASPH epitope-specific MAbs, and compositions comprising them, as agents in therapeutic and diagnostic applications to interact with target molecules in cell-free samples, cell- and tissue-based assays, animal models, and in a subject are also disclosed. Other aspects of the invention relate to use of the molecules disclosed herein to diagnose, ameliorate, or treat cell proliferation disorders and related diseases.

BACKGROUND OF THE INVENTION

Aspartyl(asparaginyl)-β-hydroxylase (ASPH) is an iron-dependent dioxygenase that catalyzes the hydroxylation of 13 carbons of aspartic acid and asparagine residues in calcium binding Epidermal Growth Factor (cbEGF)-like domains of a variety of proteins, including Notch and Notch ligand homologs (Dinchuk, Focht et al. 2002) extracellular matrix proteins, and low density lipoprotein (LDL) receptors. ASPH was first observed to be involved in the hydroxylation of a specific aspartic acid residue in the blood coagulation cascade proteins (Drakenberg, Fernlund et al. 1983) where the hydroxylated residue is underlined in the consensus sequence CX[D/N]X₄[Y/F]XC. The role of hydroxylated residue is presently unknown, but the sole known crystal structure with a beta-hydroxylated asparagine (PDB ID 5JZZ: McDonough, M. A., Pfeffer, I., and Munzel (2016) Aspartyl/Asparaginyl beta-hydroxylase (AspH)oxygenase and TPR domains in complex with manganese, N-oxalylglycine and cyclic peptide substrate mimic of factor X. DOI: 10.2210/pdb5JZZ/pdb).

ASPH is generally classified as a peptide-aspartate beta-dioxygenase (EC 1.14.11.16), a member of the alpha-ketoglutarate-dependent hydroxylases superfamily, which catalyzes the following chemical reaction, facilitated by iron as a cofactor. peptide-L-aspartate+2-oxoglutarate+O₂⇄peptide-3-hydroxy-L-aspartate+succinate+CO₂  (Reaction 1)

ASPH is not normally expressed in adult cells (Lavaissiere, Jia et al. 1996), but is expressed during invasion of the uterine wall by trophoblasts during development of the placenta (Gundogan, Elwood et al. 2007). ASPH is overexpressed in a variety of tumors, including hepatocellular, cholangiocarcinoma, gastric cancer, pancreatic cancer, non-small cell lung cancer, glioblastoma multiform, osteosarcoma, cervical cancer, ovarian cancer and breast cancer (Yang, Song et al. 2010), and enhances signaling in the Notch pathway (Cantarini, de la Monte et al. 2006).

FIG. 1 sets forth an illustration showing the Activation of Notch Signaling Pathway by ASPH. FIGS. 2 and 3 set forth illustrations showing the Locations of Epitopes of Interest on ASPH.

Known and computationally predicted ASPH substrates are illustrated in FIG. 4 and FIG. 5. Prediction of ASPH substrates is based upon the protein possessing A) a cbEGF domain and B) the consensus sequence CX[D/N]X₄[Y/F]XC. Of particular interest are nearly all of the Notch signaling proteins, not only including the receptors Notch1-4, but many of the known ligands such as Jagged1&2 and DII1&4, but also known Notch pathway modulator human homologues of Crumbs from Drosophila. ASPH is known to hydroxylate lipid receptor proteins, including Lrp1. Lrp1 is known to have an interaction with Wnt5a of the canonical Wnt signaling pathway (El Asmar, Terrand et al. 2016). ASPH substrate Gas6 is the ligand of the Tyro3, Axel and Mer (TAM) kinases, which have been implicated in cancer (Wu, Ma et al. 2018). Known ASPH substrates including the fibrillins are involved in the release of TGF-beta, which is implicated in cancer (Furler, Nixon et al. 2018). In addition to cancer, ASPH hydroxylated substrates are found in nearly all of the blood coagulation proteins involved in thrombosis (see panel C in FIG. 4), and many of the proteins involved in lipid uptake including LDLR, VLDLR and Lrp1 (see panel B in FIG. 4) and cholesterol homeostasis. Thus, ASPH expression is expected to have a cascade of effects, but may have particular value in the treatment of cancer, as well as thrombosis and lipid/cholesterol associated cardiovascular diseases.

ASPH is known to contain multiple phosphorylation sites (Tong, Gao et al. 2013), including T748. Phosphorylation of ASPH is known to alter the expression and function of ASPH (Borgas, Gao et al. 2015), and plays a potential role in migration and tissue invasion of hepatocellular carcinoma (Borgas, Gao et al. 2015). Antibodies selective for ASPH phosphorylation state should be useful in the diagnosis of cancer and distinguishing normally expressed ASPH from tumor expressed ASPH.

Previously designed antibodies to ASPH did not result in direct suppression of tumor cell proliferation (Yeung, Finney et al. 2007). Despite the high affinity of these antibodies, the targeted epitope did not sufficiently disrupt catalytic activity of ASPH. Consequently, while the antibodies were internalized into the cancer cells expressing ASPH, there was no direct antibody activity leading to cellular senescence or cytotoxicity. To address this issue, radioisotopes have been conjugated to previously described high affinity ASPH antibodies, leading to modest activity (Revskaya, Jiang et al. 2017). Other previous anti-ASPH strategies include small molecule inhibitors of ASPH (Aihara, Huang et al. 2014), a dendritic cell approach (Noda, Shimoda et al. 2012), and a vaccine approach (Iwagami, Casulli et al. 2017).

This application describes the epitope selection for phospho-selective ASPH antibodies, as well as antibodies for ASPH catalytic activity inhibition, including epitopes on both the catalytic and non-catalytic domains, demonstration of high affinity for ASPH, strong IHC staining of cancerous but not normal tissue, and direct activity against cancer cells.

SUMMARY OF THE INVENTION

The present invention relates to monoclonal antibodies (MAbs) targeting one or more specific epitopes of aspartyl (asparaginyl) β-hydroxylase (ASPH), including chimeric and humanized MAb variants, and fragments thereof (collectively ASPH epitope-specific MAbs, or simply ASPH MAbs), are disclosed. Methods of production, purification, and use of the ASPH epitope-specific MAbs, and compositions comprising them, as agents in therapeutic and diagnostic applications to interact with target molecules in cell-free samples, cell- and tissue-based assays, animal models, and in a subject are also disclosed. Other aspects of the invention relate to use of the molecules disclosed herein to diagnose, ameliorate, or treat cell proliferation disorders and related diseases.

One aspect relates to an isolated monoclonal antibody, or a fragment thereof, which binds to a one or more peptide epitopes of human aspartyl (asparaginyl) β-hydroxylase (ASPH), wherein at least one of said peptide epitopes is located within or adjacent to the catalytic domain of ASPH.

Another aspect relates to a composition comprising any of the antibodies noted above, including compositions comprising at least one antibody that targets ASPH and one or more pharmaceutical excipients.

Another aspect relates to a method of using any of the antibodies noted above, to inhibit the proliferation of isolated tumor cell samples grown in culture.

Another aspect relates to a method of using any of the antibodies noted above, to inhibit the proliferation of tumor cells in tissue samples grown in culture.

Another aspect relates to a method of treating cancer in a mammalian subject, comprising administering to a subject in need thereof an antibody as noted above in an amount sufficient to treat cancer.

Another aspect relates to a kit for diagnosis of cancer in a mammalian subject, wherein said kit comprises an antibody, or a fragment thereof, of any of any of the antibodies noted above.

Another aspect relates to a humanized antibody comprising one or more complementarity determining regions (CDRs) derived from a non-human source targeting one or more peptide epitopes located within or adjacent to the catalytic domain of ASPH of any of the antibodies noted above, and one or more portions of the constant regions of a human antibody, and fragments thereof.

Another aspect relates to a bispecific antibody comprising one or more complementarity determining regions (CDRs) derived from a non-human source targeting one or more peptide epitopes located within or adjacent to the catalytic domain of ASPH of any of the antibodies noted above, and an antibody targeting other epitopes selected from the group consisting of the T-cell redirector class, comprising an antibody targeting one or more ASPH CDRs and an antibody targeting CD3; the NK-cell redirector class, comprising an antibody targeting one or more ASPH CDRs and an antibody targeting CD16A; the tumor targeting immunomodular class, comprising an antibody targeting one or more ASPH CDRs and an antibody targeting CD40 or 4-1BB; and the dual immunomodular class, comprising an antibody targeting one or more ASPH CDRs and an antibody targeting PD-L1, PD-1, CTLA-4, TGF-β, LAG-3, TIM-3, or OX40.

A better understanding of the invention will be obtained from the following detailed descriptions and accompanying drawings, which set forth illustrative embodiments that are indicative of the various ways in which the principals of the invention may be employed.

BRIEF DESCRIPTION OF THE DRAWINGS

Statement Concerning Aspects of the Invention Understood by Reference to the Drawings

The foregoing aspects and many of the attendant advantages of this invention will become more readily appreciated as the same become better understood by reference to the following detailed description, when taken in conjunction with the accompanying drawings, wherein:

FIG. 1 sets forth an illustration showing the Activation of Notch Signaling Pathway by ASPH. Aspartyl(asparaginyl)-β-hydroxylase (ASPH) is an iron-dependent dioxygenase that catalyzes the hydroxylation of 13 carbons of aspartic acid and asparagine residues in domains of a variety of proteins, including Notch and Notch ligand homologs. Intense activation of the Notch pathway by ASPH is observed in tumor tissues. Inhibition of ASPH allows normal activation of the Notch Pathway.

FIG. 2A sets forth an illustration showing the Locations of Epitopes of Interest on Human ASPH (3D Structure). FIG. 2B lists peptide domain sequences.

FIG. 3 sets forth an illustration showing the Locations of Epitopes of Interest on the Sequence of ASPH.

FIG. 4 (Panels A-H, plus a polypeptide domain key) sets forth an illustration showing experimentally confirmed and computationally predicted substrates of ASPH, including those found in the following types of proteins: A. Notch signaling pathway, B. Lipid receptors, C. Blood coagulation cascade proteins, D. Thrombospondins, E. Complement cascade proteins, F. FAT cadherin domain proteins, G. Bone associated proteins, and H. 7-transmembrane domain containing proteins.

FIG. 5 (Panels A-G, plus a polypeptide domain key) sets forth an illustration showing experimentally confirmed and computationally predicted substrates of ASPH (continued), including those found in the following types of proteins: A. TGF-b containing proteins, B. Platelet associated proteins, C. Eye/retina associated proteins, D. Mammary cancer metastasis proteins, E. Slit proteins, F. Miscellaneous proteins, and G. Drosophila homologues.

FIG. 6 sets forth an illustration demonstrating positive 5H4/5K3 staining visualized with DAB (brown) on Human Hepatocellular Carcinoma at 4 μg/ml, 8 μg/ml, and 10 μg/ml (3 images). No-primary negative control was performed to identify nonspecific secondary binding (Neg, bottom right image). The scale bar represents 20 μm.

FIG. 7 sets forth an illustration demonstrating positive 9H2/9K1 staining visualized with DAB (brown) on Human Hepatocellular Carcinoma at 4 μg/ml, 8 μg/ml, and 10 μg/ml (3 images). No-primary negative control was performed to identify nonspecific secondary binding (Neg, bottom right image). The scale bar represents 20 μm.

FIG. 8 sets forth an illustration demonstrating 5H4/5K3 Phase III on TMAs for samples labeled as LV12 Core F4 (top image), and LV12 Core F4-Isotype (bottom image). Positive 5H4/5K3 staining was visualized with DAB (brown) on TMAs (LV12 Core F4, top image). Isotype negative control was performed with Rabbit IgG (bottom image). The scale bar represents 20 μm.

FIG. 9 sets forth an illustration demonstrating 5H4/5K3 Phase III on TMAs for samples labeled as PCO2 Core A6 (top image), and PCO2 Core A6-Isotype (bottom image). Positive 5H4/5K3 staining was visualized with DAB (brown, top image). Isotype negative control was performed with Rabbit IgG (bottom image). The scale bar represents 20 μm.

FIG. 10 sets forth an illustration demonstrating 5H4/5K3 Phase III on TMAs for samples labeled as OV03 Core C5 (top image), and OV03 Core C5-Isotype (bottom image). Positive 5H4/5K3 staining was visualized with DAB (brown, top image). Isotype negative control was performed with Rabbit IgG (bottom image). The scale bar represents 20 μm.

FIG. 11 sets forth an illustration demonstrating 5H4/5K3 Phase III on TMAs for samples labeled as OV01 Core D2 (top image), and OV01 Core D2-Isotype (bottom image). Positive 5H4/5K3 staining was visualized with DAB (brown, top image). Isotype negative control was performed with Rabbit IgG (bottom image). The scale bar represents 20 μm.

FIG. 12 sets forth an illustration demonstrating activity of 5H4/5K3 Against Granulosa Cell Tumor Samples (A11 and B11). Positive 5H4/5K3 staining was visualized with DAB (brown) Against Granulosa Cell Tumor (top images, A11 and B11) Isotype negative control was performed with Rabbit IgG (bottom images, A11 and B11).

FIG. 13 sets forth an illustration demonstrating activity of 5H4/5K3 Against Serrous Cystadenocarcinoma Stage III Samples (C5 and D5). Positive 5H4/5K3 staining was visualized with DAB (brown) against Serrous Cystadenocarcinoma Stage III (top images, C5 and D5). Isotype negative control was performed with Rabbit IgG (bottom images, C5 and D5).

FIG. 14 sets forth an illustration demonstrating activity of 5H4/5K3 Against Serrous Cystadenocarcinoma Stage III Samples (C8 and D8). Positive 5H4/5K3 staining was visualized with DAB (brown) against Serrous Cystadenocarcinoma Stage III (top images, C8 and D8). Isotype negative control was performed with Rabbit IgG (bottom images, C8 and D8).

FIG. 15 sets forth an illustration demonstrating activity of 5H4/5K3 Against Endometrioid Adenocarcinoma Stage III Samples (E8 and F8). Positive 5H4/5K3 staining was visualized with DAB (brown) against Endometrioid Adenocarcinoma Stage III (top images, E8 and F8). Isotype negative control was performed with Rabbit IgG (bottom images, E8 and F8).

FIG. 16 sets forth an illustration demonstrating reaction of 5H4/5K3 Against Normal Ovarian Tissue Samples (A1 and B1). Lack of 5H4/5K3 staining by DAB against Normal Ovarian Tissue is shown in top images, A1 and B1. Isotype negative control was performed with Rabbit IgG (bottom images, A1 and B1).

FIG. 17 sets forth an illustration demonstrating reaction of 5H4/5K3 against Thecoma (Theca Cell) Tumor Tissue (A5 and B5). 5H4/5K3 staining was visualized with DAB (brown, top images) against Thecoma (Theca Cell) Tumor Tissue (A5 and B5). Isotype negative control was performed with Rabbit IgG (bottom images, A5 and B5).

FIG. 18 sets forth an illustration demonstrating Immobilization of Protein G on Channels 1 (Red, top line) and 2 (Blue, bottom line) followed by Capture of Antibody on Channel 1.

FIG. 19 sets forth an illustration demonstrating Interaction of ASPH with Mock sample. Concentrations are 500 nM (dark red, top line on right portion of the graph), 250 nM (light green), 125 nM (blue), 62.5 nM (dark green) 31.2 nM (orange), 15.6 nM (red).

FIG. 20 sets forth an illustration demonstrating Interaction of ASPH with 2H4/2K5. Concentrations are 500 nM (dark red, 1^(st) line from top), 250 nM (light green, 2^(nd) and 3^(rd) lines from top), 125 nM (blue, 4^(th) and 5^(th) lines from top), and 62.5 nM (dark green, 6^(th) and 7^(th) lines from top).

FIG. 21 Interaction of ASPH with 5H1/5K1. Concentrations are 500 nM (dark red, 1^(st) line from top), 250 nM (light green, 2^(nd) and 3^(rd) lines from top), 125 nM (blue, 4^(th) and 5^(th) lines from top), 62.5 nM (dark green, 6^(th) and 7^(th) lines from top), 31.2 nM (orange, 8^(th) and 9^(th) lines from top), and 15.6 nM (red, 10^(th) and 11^(th) lines from top).

FIG. 22 sets forth an illustration demonstrating Interaction of ASPH with 5H4/5K3. Concentrations are 500 nM (dark red, 1^(st) and 2^(nd) lines from top), 250 nM (light green, 3^(rd) and 4^(th) lines from top), 125 nM (blue, 5^(th) and 6^(th) lines from top), 62.5 nM (dark green, 7^(th) and 8^(th) lines from top), 31.2 nM (orange, 9^(th) and 10^(th) lines from top), and 15.6 nM (red, 11^(th) and 12^(th) lines from top).

FIG. 23 sets forth an illustration demonstrating Interaction of ASPH with 9H2/9K1. Concentrations are 500 nM (dark red, 1^(st) and 2^(nd) lines from top), 250 nM (light green, 3^(rd) and 4^(th) lines from top), 125 nM (blue, 5^(th) and 6^(th) lines from top), 62.5 nM (dark green, 7^(th) and 8^(th) lines from top), 31.2 nM (orange, 9^(th) and 10^(th) lines from top), and 15.6 nM (red, 11^(th) and 12^(th) lines from top).

FIG. 24 sets forth an illustration demonstrating Interaction of ASPH with 9H2/9K3. Concentrations are 500 nM (dark red, 1^(st) line from top), 250 nM (light green, 2^(nd) and 3^(rd) lines from top), 125 nM (blue, 4^(th) and 5^(th) lines from top), 62.5 nM (dark green, 6^(th) line from top), and 31.2 nM (orange, 7^(th) line from top).

FIG. 25 sets forth an illustration demonstrating Interaction of ASPH with 8H1/8K1. Concentrations are 500 nM (dark red, first and second lines from the top), 250 nM (light green), 125 nM (blue), 62.5 nM (dark green) 31.2 nM (orange), 15.6 nM (red).

FIG. 26 sets forth an illustration demonstrating IC50 Curves for 5H4/5K3, 9H2/9K1 and Mock Antibody Samples Carried Out in 4T1 Cells.

FIG. 27 sets forth an illustration demonstrating IC50 Curves for 5H4/5K3, 9H2/9K1 and Mock Antibody Samples Carried Out in MCF7 Cells.

FIG. 28 sets forth an illustration demonstrating IC50 Curves for 5H4/5K3, 9H2/9K1 and Mock Antibody Samples Carried Out in MV411 Cells.

TABLE #T0 Summary of Staining Patterns in Panels of Photographic Images of Cell Samples (from +++ to −)* Top/Top Top Bottom/ Bottom Figure Description Left Right Bottom Left Right 6 Positive 5H4/5K3 staining visualized + ++ +++ − with DAB (brown) on Human Hepatocellular Carcinoma at 4 μg/ml, 8 μg/ml, and 10 μg/ml (3 images). No-primary negative control was performed to identify nonspecific secondary binding (Neg, bottom right image). 7 Positive 9H2/9K1 staining visualized (+) + ++ − with DAB (brown) on Human Hepatocellular Carcinoma at 4 μg/ml, 8 μg/ml, and 10 μg/ml (3 images). No-primary negative control was performed to identify nonspecific secondary binding (Neg, bottom right image). 8 5H4/5K3 Phase III on TMAs for samples +++ − labeled as LV12 Core F4 (top image), and LV12 Core F4 - Isotype (bottom image). 9 5H4/5K3 Phase III on TMAs for samples +++ − labeled as PC02 Core A6 (top image), and PC02 Core A6 - Isotype (bottom image). Positive 5H4/5K3 staining was visualized with DAB (brown,, top image). Isotype negative control was performed with Rabbit IgG (bottom image). 10 5H4/5K3 Phase III on TMAs for samples +++ − labeled as OV03 Core C5 (top image), and OV03 Core C5 - Isotype (bottom image). Positive 5H4/5K3 staining was visualized with DAB (brown, top image). Isotype negative control was performed with Rabbit IgG (bottom image). 11 5H4/5K3 Phase III on TMAs for samples +++ − labeled as OV01 Core D2 (top image), and OV01 Core D2 - Isotype (bottom image). Positive 5H4/5K3 staining was visualized with DAB (brown, top image). Isotype negative control was performed with Rabbit IgG (bottom image). 12 Activity of 5H4/5K3 Against Granulosa ++ ++ − − Cell Tumor Samples (A11 and B11). Positive 5H4/5K3 staining was visualized with DAB (brown) Against Granulosa Cell Tumor (top images, A11 and B11) Isotype negative control was performed with Rabbit IgG (bottom images, A11 and B11). 13 Activity of 5H4/5K3 Against Serrous +++ +++ − − Cystadenocarcinoma Stage III Samples (C5 and D5). Positive 5H4/5K3 staining was visualized with DAB (brown) Against Serrous Cystadenocarcinoma Stage III (top images, C5 and D5) Isotype negative control was performed with Rabbit IgG(bottom images, C5 and D5). 14 Activity of 5H4/5K3 Against +++ +++ − − Serrous Cystadenocarcinoma Stage III Samples (C8 and D8). Positive 5H4/5K3 staining was visualized with DAB (brown) Against Serrous Cystadenocarcinoma Stage III (top images, C8 and D8) Isotype negative control was performed with Rabbit IgG (bottom images, C8 and D8). 15 Activity of 5H4/5K3 Against +++ +++ (−) (−) Endometrioid Adenocarcinoma Stage III Samples (E8 and F8). Positive 5H4/5K3 staining was visualized with DAB (brown) Against Endometrioid Adenocarcinoma Stage III (top images, E8 and F8). Isotype negative control was performed with Rabbit IgG (bottom images, E8 and F8). 16 Reaction of 5H4/5K3 Against Normal − − − − Ovarian Tissue Samples (A1 and B1). Lack of 5H4/5K3 staining by DAB Against Normal Ovarian Tissue (top images, A1 and B1). Isotype negative control was performed with Rabbit IgG (bottom images, A1 and B1). 17 Reaction of 5H4/5K3 Against Thecoma (+) (+) − − (Theca Cell) Tumor Tissue (A5 and B5). 5H4/5K3 staining was visualized with DAB (brown, top images) Against Thecoma (Theca Cell) Tumor Tissue (A5 and B5). Isotype negative control was performed with Rabbit IgG (bottom images, A5 and B5). *Staining intensities of different panels for each sample were evaluated on a scale from +++, ++, +, (+), (−), and − where reaction with DAB to produce an intense brown color after reaction with cells was designated as +++, to −, where all cells were mostly blue or white.

Terms and Definitions

The following is a list of abbreviations, plus terms and their definitions, used throughout the specification and the claims:

General abbreviations and their corresponding meanings include: aa or AA=amino acid; mg=milligram(s); ml or mL=milliliter(s); mm=millimeter(s); mM=millimolar; nmol=nanomole(s); pmol=picomole(s); ppm=parts per million; RT=room temperature; U=units; μg, μg=micro gram(s); ul, μl=micro liter(s); μM, μM=micromolar.

Specific Abbreviations and their Corresponding Meanings Include

The terms “cell” and “cells”, which are meant to be inclusive, refer to one or more cells which can be in an isolated or cultured state, as in a cell line comprising a homogeneous or heterogeneous population of cells, or in a tissue sample, or as part of an organism, such as a transgenic animal.

The term “amino acid” encompasses both naturally occurring and non-naturally occurring amino acids unless otherwise designated.

The term “complementarity-determining regions” or “CDRs” are defined by Wikipedia, as part of the variable chains in immunoglobulins (antibodies) and T cell receptors, generated by B-cells and T-cells respectively, where these molecules bind to their specific antigen. CDRs, which comprise the most variable parts of antibodies, are crucial to the diversity of antigen specificities generated by lymphocytes.

The term “paratope” refers to a set of CDRs.

DETAILED DESCRIPTION OF THE INVENTION

The present invention relates to monoclonal antibodies (MAbs) targeting one or more specific epitopes of aspartyl (asparaginyl) β-hydroxylase (ASPH), including chimeric and humanized MAb variants, and fragments thereof (collectively ASPH epitope-specific MAbs, or simply ASPH MAbs), are disclosed. Methods of production, purification, and use of the ASPH epitope-specific MAbs, and compositions comprising them, as agents in therapeutic and diagnostic applications to interact with target molecules in cell-free samples, cell- and tissue-based assays, animal models, and in a subject are also disclosed. Other aspects of the invention relate to use of the molecules disclosed herein to diagnose, ameliorate, or treat cell proliferation disorders and related diseases.

One aspect relates to an isolated monoclonal antibody, or a fragment thereof, which binds to a one or more peptide epitopes of human aspartyl (asparaginyl) β-hydroxylase (ASPH), wherein at least one of said peptide epitopes is located within or adjacent to the catalytic domain of ASPH.

Another aspect relates to an antibody, or a fragment thereof, as noted above, wherein at least one of said peptide epitopes located within or adjacent to the catalytic domain of ASPH is located within 30 amino acids of the C-terminus of ASPH.

Another aspect relates to an antibody, which binds to one or more synthetic peptides selected from the group consisting of (a) a synthetic peptide comprising 29 amino acids with Cysteine at its amino terminus, plus 28 amino acids corresponding to positions 731-758 at the C-terminal end of human ASPH, with the Threonine at 19 (corresponding to 748 of ASPH) phosphorylated, as CASSFRLIFIVDVWHPEL-T(PO3H2)-PQQRRSLPAI represented by SEQ ID NO: 19; and (b) a synthetic peptide comprising 29 amino acids with Cysteine at its amino terminus, plus 28 amino acids corresponding to positions 731-758 at the C-terminal end of human ASPH, as CASSFRLIFIVDVWHPELTPQQRRSLPAI represented by SEQ ID NO: 20.

Related aspects include an antibody, which binds to an epitope comprising at least 4 consecutive amino acid residues located within 30 amino acids from the C-terminal end of human ASPH, including an antibody wherein said epitope comprising at least 4 consecutive amino acid residues located within 30 amino acids from the C-terminal end of human ASPH comprises the consecutive amino acid selected from the group consisting of

PELT represented by SEQ ID NO: 42,

ELTP represented by SEQ ID NO: 43,

LTPQ represented by SEQ ID NO: 44,

TPQQ represented by SEQ ID NO: 45,

PQQR represented by SEQ ID NO: 46,

QQRR represented by SEQ ID NO: 47,

QRRS represented by SEQ ID NO: 48,

RRSL represented by SEQ ID NO: 49,

RSLP represented by SEQ ID NO: 50,

SLPA represented by SEQ ID NO: 51, and

LPAI represented by SEQ ID NO: 52.

Related aspects also include an antibody, wherein said peptide epitope comprises a phosphorylated threonine, T(PO3H2).

Another aspect relates to an isolated monoclonal antibody, or a fragment thereof, which binds to a one or more peptide epitopes of human aspartyl (asparaginyl) β-hydroxylase (ASPH), wherein said antibody comprises a recombinant heavy chain and a recombinant light chain, wherein said recombinant heavy chain comprises a polypeptide sequence selected from the group consisting of SEQ ID NOS 21-25; and wherein said recombinant light chain comprises a polypeptide sequence selected from the group consisting of SEQ ID NOS 26-30.

Another aspect relates to an antibody selected from the group consisting of 5H4/5K3 and 9H2/9K1, wherein antibody 5H4/5K3 comprises a heavy chain designated 5H4, represented by the sequence SEQ ID NO: 25, and a light chain 5K3 represented by the sequence SEQ ID NO: 27; and wherein antibody 9H2/9K1 comprises a heavy chain designated 9H2, represented by the sequence SEQ ID NO: 29, and a light chain 9K1 represented by the sequence SEQ ID NO: 30.

Another aspect relates to an isolated monoclonal antibody, or a fragment thereof, which binds to a one or more peptide epitopes of human aspartyl (asparaginyl) β-hydroxylase (ASPH), wherein said antibody comprises a recombinant heavy chain comprising:

-   -   a CDR1 comprising a sequence selected from the group consisting         of NFMC (SEQ ID NO: 31), corresponding to residues 50-53 of SEQ         ID NO: 21, and NAMC (SEQ ID NO: 32), corresponding to residues         50-53 of SEQ ID NOS: 23, 29, 24, and 25;     -   a CDR2 comprising a sequence selected from the group consisting         of CIYF (SEQ ID NO: 33) corresponding to residues 68-71 of SEQ         ID NO: 21 and CIDN (SEQ ID NO: 34) corresponding to residues         68-71 of SEQ ID NO: 23, 29, 24, and 25;     -   a CDR3 comprising a sequence selected from the group consisting         of DGPGSISWKI (SEQ ID NO: 35) corresponding to residues 117-126         of SEQ ID NO: 21, and NFNI (SEQ ID NO: 36) corresponding to         residues 116-119 of SEQ ID NOS: 23, 29, 24, and 25.

Another aspect relates to an isolated monoclonal antibody, or a fragment thereof, which binds to a one or more peptide epitopes of human aspartyl (asparaginyl) β-hydroxylase (ASPH), wherein said antibody comprises a recombinant light chain comprising

-   -   a CDR1 comprising a sequence selected from the group consisting         of SVYSKNR (SEQ ID NO: 37) corresponding to residues 50-56 of         SEQ ID NO: 22, and SVYDNNR SEQ ID NO: 38) corresponding to         residues 50-56 of SEQ ID NOS: 26, 27, 28, and 30,     -   a CDR2 comprising the sequence LAS (SEQ ID NO: 39) corresponding         to residues 78-80 of SEQ ID NOS: 22, 26, 27, 28, and 30;     -   a CDR3 comprising a sequence selected from the group consisting         of QGTYDSSGWYWA (SEQ ID NO: 40) corresponding to residues         113-124 of SEQ ID NO: 22, and LGSYSGYIYI (SEQ ID NO: 41)         corresponding to residues 113-122 of SEQ ID NOS: 26, 27, 28, and         30.

Related aspects include variants of the monoclonal antibodies or fragments thereof, that contain one or more conservative amino acid substitutions in which the functional activity relating to binding of the antibody or fragment thereof to an epitope of ASPH is retained. Related aspects also include truncated or fusion variants of the monoclonal antibodies comprising one or more insertions or deletions of amino acids in which the in which the functional activity relating to binding of the antibody or fragment thereof to an epitope of ASPH is retained. Related aspects also include variants comprising one or more combinations of conservative amino acid substitutions, insertions, and deletions, particularly where the number of residues that are altered by substitution, insertion, or deletion is small, such as 1, 2, 3, 4, 5, 6, 7, 8, 9, or 10, 11-15, 16-20, and 21-25 residues compared to the parent antibody molecule. Related aspects also include molecules having one or more larger insertions or deletions of amino acid residues or polypeptide domains that do not alter the functional binding activity of the antibody to a desired epitope in a target molecule.

Another aspect relates to a composition comprising any of the antibodies noted above, including compositions comprising at least one antibody that targets ASPH and one or more pharmaceutical excipients.

Another aspect relates to a method of using any of the antibodies noted above, to inhibit the proliferation of isolated tumor cell samples grown in culture.

Another aspect relates to a method of using any of the antibodies noted above, to inhibit the proliferation of tumor cells in tissue samples grown in culture.

Another aspect relates to a method of treating cancer in a mammalian subject, comprising administering to a subject in need thereof an antibody as noted above in an amount sufficient to treat cancer. Related aspects include methods wherein said mammalian subject is a selected from the group consisting of a human, non-human primate, canine, feline, bovine, equine, and a porcine subject. A preferred aspect relates to a method, wherein said mammalian subject is a human subject.

Related aspects also include methods noted above wherein said cancer is selected from the group consisting of cancers of the liver, hepatocellular carcinoma and cholangiocarcinoma, pancreatic cancer, gastric cancer, colon cancer, kidney cancer, non-small cell lung cancer, breast cancer, ovarian cancer, cervical cancer, head-and-neck cancers secondary to human papilloma virus infection, prostate cancer, brain cancer, glioblastoma multiform, neuroblastoma, retinoblastoma, and medulloblastoma, and osteosarcoma.

Another aspect relates to a kit for diagnosis of cancer in a mammalian subject, wherein said kit comprises an antibody, or a fragment thereof, of any of any of the antibodies noted above.

Another aspect relates to a humanized antibody comprising one or more complementarity determining regions (CDRs) derived from a non-human source targeting one or more peptide epitopes located within or adjacent to the catalytic domain of ASPH of any of claims 1-10, and one or more portions of the constant regions of a human antibody, and fragments thereof.

Another aspect relates to a bispecific antibody comprising one or more complementarity determining regions (CDRs) derived from a non-human source targeting one or more peptide epitopes located within or adjacent to the catalytic domain of ASPH of any of claims 1-10, and an antibody targeting other epitopes selected from the group consisting of the T-cell redirector class, comprising an antibody targeting one or more ASPH CDRs and an antibody targeting CD3; the NK-cell redirector class, comprising an antibody targeting one or more ASPH CDRs and an antibody targeting CD16A; the tumor targeting immunomodular class, comprising an antibody targeting one or more ASPH CDRs and an antibody targeting CD40 or 4-1BB; and the dual immunomodular class, comprising an antibody targeting one or more ASPH CDRs and an antibody targeting PD-L1, PD-1, CTLA-4, TGF-β, LAG-3, TIM-3, or OX40.

Therapeutic Uses of Compositions Comprising Compounds of the Invention

Antibodies with direct activity against ASPH antibodies should be useful in the discovery and development of therapeutic drug products intended for use in the treatment of a variety of cancers. These include cancers of the liver, such as hepatocellular carcinoma and cholangiocarcinoma, pancreatic cancer, gastric cancer, colon cancer, kidney cancer, non-small cell lung cancer, breast cancer, ovarian cancer, cervical cancer, head-and-neck cancers secondary to human papilloma virus infection, prostate cancer, brain cancers of various types, including glioblastoma multiform, neuroblastoma, retinoblastoma, and medulloblastoma, and osteosarcoma.

Pharmaceutical Compositions

Related aspects of the invention are directed to compositions, including pharmaceutical compositions, comprising the compounds of the invention, noted above. One aspect of the invention is directed to a pharmaceutical composition comprising at least one pharmaceutically acceptable excipient and a therapeutically effective amount of the compound or salt disclosed above. Still another aspect of the invention relates to a method for pharmaceutical formulation of previously described compounds for use in oral and intravenous applications, and in implantable materials.

Another aspect of the present invention relates to a pharmaceutical composition including a pharmaceutically acceptable carrier and a compound according to the aspects of the present invention. The pharmaceutical composition can contain one or more of the above-identified compounds of the present invention.

Various Modifications and Alternatives, Generally

While specific aspects of the invention have been described in detail, it will be appreciated by those skilled in the art that various modifications and alternatives to those details could be developed in light of the overall teachings of the disclosure. Accordingly, the particular arrangements disclosed are meant to be illustrative only, and not limiting as to the scope of the invention, which is to be given the full breadth of the appended claims, and any equivalent, thereof.

EXAMPLES

The foregoing discussion may be better understood in connection with the following representative examples which are presented for purposes of illustrating the principle methods and compositions of the invention, and not by way of limitation. Various other examples will be apparent to the person skilled in the art after reading the present disclosure without departing from the spirit and scope of the invention. It is intended that all such other examples be included within the scope of the appended claims.

General Materials and Methods

All parts are by weight (e.g., % w/w), and temperatures are in degrees centigrade (° C.), unless otherwise indicated. Table #T1 presents a summary of the nucleotide and amino acid sequences described in this application.

TABLE #T1 Summary of Sequence ID Numbers Name Description Length Type SEQ ID NO: Human ASPH Polypeptide corresponding to Human ASPH 758 AA 01 deposited as GenBank Accession No Q12797, starting at the N-terminus with MAQRKNAKSS and ending at the C-terminus with PQQRRSLPAI Canine ASPH Polypeptide corresponding to Canine 798 AA 02 ASPH deposited as GenBank Accession No XP_022267901, starting at the N- terminus with MAEETKHGGH and ending at the C-terminus with PQQRHSLPAI Peptide #H1 KRRSNEVLR corresponding to residues   9 AA 03 391-399 of human ASPH Peptide #H2 DRQQFLGHM corresponding to residues   9 AA 04 428-436 of human ASPH Peptide #H3 GYLLIGDNDN corresponding to residues  10 AA 05 463-470 of human ASPH Peptide #H4 RSLYNVNG corresponding to residues   8 AA 06 562-569 of human ASPH Peptide #H5 PQQRRSLPAI corresponding to residues  10 AA 07 749-758 of human ASPH Peptide #H6 FLPEDENLRE corresponding to residues  10 AA 08 612-621 of human ASPH Peptide #H7 VWPHTGPTNC corresponding to residues  10 AA 09 676-685 of human ASPH Peptide #H8 LWQQGRRNE corresponding to residues   9 AA 10 630-638 of human ASPH Peptide #C1 KRRSNEVLR corresponding to residues   9 AA 11 427-435 of canine ASPH Peptide #C2 DRQQFLGHM corresponding to residues   9 AA 12 464-472 of canine ASPH Peptide #C3 GYLLIGDNNN corresponding to residues  10 AA 13 499-508 of canine ASPH Peptide #C4 RSLYNVHG corresponding to residues   8 AA 14 598-605 of canine ASPH Peptide #C5 PQQRHSLPAI corresponding to residues  10 AA 15 785-794 of canine ASPH Peptide #C6 FLPEDENLRE corresponding to residues  10 AA 16 648-657 of canine ASPH Peptide #C7 VWPHTGPTNC corresponding to residues  10 AA 17 712-721 of canine ASPH Peptide #C8 LWQQGRKINE corresponding to residues   9 AA 18 666-674 of canine ASPH Peptide #1 Synthetic peptide comprising 29 amino  29 AA 19 (CASSF- acids with Cysteine at its amino PO3H2) terminus, plus 28 amino acids corresponding to positions 731-758 at the C-terminal end of human ASPH, with the Threonine at 19 (corresponding to 748 of ASPH) phosphorylated. CASSFRLIFIVDVWHPEL-T(PO3H2)-PQQRRSLPAI Peptide #2 Synthetic peptide comprising 29 amino  29 AA 20 acids with Cysteine at its amino terminus, plus 28 amino acids corresponding to positions 731-758 at the C-terminal end of human ASPH. CASSFRLIFIVDVWHPELTPQQRRSLPAI Clone 1H2 Translated variable region of Clone ID 150 AA 21 #1H2 comprising a GQPK sequence at the start of the constant region for a heavy chain sequence. METGLRWLLLVAVLKGVQCQSLEESGGDLVKPGASLTLT CTASGLSFSDNFMCWVRQAPGKGLEWIACIYFDSSGITY YASWAKGRFTISKTSSPTVTLQMTSLTAADTATYFCARD GPGSISWDLWGQGTLVTVSSGQPKAPSVFPLAP Clone 1K6 Translated variable region of Clone ID 148 AA 22 #1K6 comprising a GDPV sequence at the start of the constant region for a kappa sequence. MDTRAPTQLLGLLLLWLPGATFAQVLTQTPSPVSAAVGG TVTISCQSSKSVYSKNRLAWYQQKPGQPPKLLIYEASKL ASGVPSRFKGSGSGTQFTLTISGVQCDDAATYYCQGTYD SSGWYWAFGGGTEVVVK

APTVLIFPPA Clone 5H1 Translated variable region of Clone ID 142 AA 23 #5H1. METGLRWLLLVAVLKGVQCQSLEESGGDLVKPGASLTLT CKASGFDFSSNAMCWVRQAPGKGPEWIACIDNGDGSTDY ATWAKGRFTISKTSSTTVTLQMTSLTAADTATYFCTRNF NLWGPGHPGHRLERTAESPVGVSTG Clone 5H3 Translated variable region of Clone ID 143 AA 24 #5H3 comprising a GQPK sequence at the start of the constant region for a heavy chain sequence. METGLRWLLLVAVLKGVQCQSLEESGGDLVKPGASLTLT CKASGFDFSSNAMCWVRQAPGKGPEWIACIDNGDGSTDY ATWAKGRFTISKTSSTTVTLQMTSLTAADTATYFCTRNF NLWGQGTLVTVSSGQPKAPSVFPLAP Clone 5H4 Translated variable region of Clone ID 143 AA 25 #5H4 comprising a GQPK sequence at the start of the constant region for a heavy chain sequence. METGLRWLLLVAVLKGVQCQSLEESGGDLVKPGASLTLT CKASGFDFSSNAMCWVRQAPGKGPEWIACIDNGDGSTDY ATWAKGRFTISKTSSTTVTLQMTSLTAADTATYFCTRNF NLWGQGTLVTVSSGQPKAPSVFPLAP Clone 5K1 Translated variable region of Clone ID 146 AA 26 #5K1 comprising a GDPV sequence at the start of the constant region for a kappa sequence. MDTRAPTQLLGLLLLWLPGATFAQVLTQTASSVSAAVGG TVTISCQSSQSVYDNNRLAWFQQKPGQPPKLLIYETSKL ASGVPLRFKGSGSGTQFTLTISDLECDDAATYYCLGSYS GYIYTFGGGTEVVVK

APTVLIFPPA Clone 5K3 Translated variable region of Clone ID 146 AA 27 #5K3 comprising a GDPV sequence at the start of the constant region for a kappa sequence. MDTRAPTQLLGLLLLWLPGATFAQVLTQTASSVSAAVGG TVTISCQSSQSVYDNNRLAWFQQKPGQPPKLLIYETSKL ASGVPLRFKGSGSGTQFTLTISDLECDDAATYYCLGSYS GYIYTFGGGTEVVVK

APTVLIFPPA Clone 5K6 Translated variable region of Clone ID 146 AA 28 #5K6 comprising a GDPV sequence at the start of the constant region for a kappa sequence. MDTRAPTQLLGLLLLWLPGATFAQVLTQTASSVSAAVGG TVTISCQSSQSVYDNNRLAWFQQKPGQPPKLLIYETSKL ASGVPLRFKGSGSGTQFTLTISDLECDDAATYYCLGSYS GYIYTFGGGTEVVVK

APTVLIFPPA Clone 9H2 Translated variable region of Clone ID 142 AA 29 #9H2 comprising a GQPK sequence at the start of the constant region for a heavy chain sequence. METGLRWLLLVAVMKGVQCQSLEESGGDLVKPGASLTLT CKASGFDFISNAMCWVRQAPGKGPEWIACIDNGDGSTDY ATWAKGRFTISKTSSTTVTLQMTSLTAADTATYFCTRNF NLWGQGTL?TVSSGQPKAPSVFPLAP Clone 9K1 Translated variable region of Clone ID 146 AA 30 #9K1 comprising a GDPV sequence at the start of the constant region for a kappa sequence. MDTRAPTQLLGLLLLWLPGATFAQVLTQTASSVSAAVGG TVTISCQSSQSVYDNNRLAWFQQKSGQPPKLLIYETSKL ASGVPLRFKGSGSGTQFTLTISDLECDDAATYYCLGSYS GYIYTFGGGTEVVVK

APTVLIFPPA Clone 1H2 CDR1 region of clone 1H2   4 AA 31 CDR1 corresponding to corresponding to residues 50-53 of SEQ ID NO: 21. NFMC Clones 5H1, CDR1 region of Clones 5H1, 9H2, 5H3,   4 AA 32 9H2, 5H3, 5H4, corresponding to residues 50-53 5H4 CDR1 of SEQ ID NOS: 23, 29, 24, and 25. NAMC Clone 1H2 The CDR2 regions from the heavy chain   4 AA 33 CDR2 clone 1H2 corresponding to residues 68-71 of SEQ ID NO: 21. CIYF Clones 5H1, The CDR2 regions from the heavy chain   4 AA 34 9H2, 5H3, clones 5H1, 9H2, 5H3, 5H4 5H4 CDR2 corresponding to residues 68-71 of SEQ ID NO: 23, 29, 24, and 25. CIDN Clone 1H2 CDR3 regions from the heavy chain clone  10 AA 35 CDR3 1H2 corresponding to residues 117-126 of SEQ ID NO: 21. DGPGSISWDI Clones 5H1, CDR3 regions from the heavy chain   4 AA 36 9H2, 5H3, clones 5H1, 9H2, 5H3, 5H4 corresponding 5H4 CDR3 to residues 116-119 of SEQ ID NOS: 23, 29, 24, and 25. NFNI Clone 1K6 The CDR1 regions from the kappa chain   7 AA 37 CDR1 clone 1K6, corresponding to residues 50-56 of SEQ ID NO: 22. SVYSKNR Clones 5K1, The CDR1 regions from the kappa chain   7 AA 38 5K3, 5K6, clones 5K1, 5K3, 5K6, and 9K1 and 9K1 corresponding to residues 50-56 of SEQ CDR1 ID NOS: 26, 27, 28, and 30. SVYDNNR Clones 1K6, The CDR2 regions from the kappa chain   3 AA 39 5K1, 5K3, clones 1K6, 5K1, 5K3, 5K6, and 9K1 5K6, and corresponding to residues 78-80 of SEQ 9K1 CDR2 ID NOS: 22, 26, 27, 28, and 30. LAS Clone 1K6 The CDR3 regions from the kappa chain  12 AA 40 CDR3 clone 1K6 corresponding to residues 113-124 of SEQ ID NO: 22. QGTYDSSGWYWA Clones 5K1, The CDR3 regions from the kappa chain  10 AA 41 5K3, 5K6, clones 5K1, 5K3, 5K6, and 9K1 and 9K1 corresponding to residues 113-122 of CDR3 SEQ ID NOS: 26, 27, 28, and 30. LGSYSGYIYI Peptide Four aa peptide corresponding to aa   4 AA 42 PELT 745-748 near the carboxy terminus of human ASPH. PELT Peptide Four aa peptide corresponding to aa   4 AA 43 ELTP 746-749 near the carboxy terminus of human ASPH. ELTP Peptide Four aa peptide corresponding to aa   4 AA 44 LTPQ 747-750 near the carboxy terminus of human ASPH. LTPQ Peptide Four aa peptide corresponding to aa   4 AA 45 TPQQ 748-751 near the carboxy terminus of human ASPH. TPQQ Peptide Four aa peptide corresponding to aa   4 AA 46 PQRR 749-752 near the carboxy terminus of human ASPH. PQQR Peptide Four aa peptide corresponding to aa   4 AA 47 QQRR 750-753 near the carboxy terminus of human ASPH. QQRR Peptide Four aa peptide corresponding to aa   4 AA 48 QRSS 751-754 near the carboxy terminus of human ASPH. QRRS Peptide Four aa peptide corresponding to aa   4 AA 49 RSSL 752-755 near the carboxy terminus of human ASPH. RRSL Peptide Four aa peptide corresponding to aa   4 AA 50 RSLP 753-756 near the carboxy terminus of human ASPH. RSLP Peptide Four aa peptide corresponding to aa   4 AA 51 SLPA 754-757 near the carboxy terminus of human ASPH. SLPA Peptide Four aa peptide corresponding to aa   4 AA 52 LPAI 746-758 near the carboxy terminus of human ASPH. LPAI

Sequence #SQ1: Locations of Peptides #H1-#H8 Along Human ASPH (758 aa) ID ASPH_HUMAN              Reviewed;         758 AA. AC Q12797; A0A0A0MSK8; A6NDF4; A6NHI2; B4DIC9; B4E2K4; B7ZM95; E5RGP5; AC F5H667; Q6NXR7; Q8TB28; Q9H291; Q9H2C4; Q9NRI0; Q9NRI1; Q9Y4J0; DT 01-NOV-1997, integrated into UniProtKB/Swiss-Prot. DT 17-APR-2007, sequence version 3. DT 25-APR-2018, entry version 181. [. . . Text omitted . . .] SQ SEQUENCE   758 AA;  85863 MW;  4AE56D1D8DF0AF0C CRC64; MAQRKNAKSS GNSSSSGSGS GSTSAGSSSP GARRETKHGG HKNGRKGGLS GTSFFTWFMV  60 IALLGVWTSV AVVWFDLVDY EEVLGKLGIY DADGDGDFDV DDAKVLLGLK ERSTSEPAVP 120 PEEAEPHTEP EEQVPVEAEP QNIEDEAKEQ IQSLLHEMVH AEHVEGEDLQ QEDGPTGEPQ 180 QEDDEFLMAT DVDDRFETLE PEVSHEETEH SYHVEETVSQ DCNQDMEEMM SEQENPDSSE 240 PVVEDERLHH DTDDVTYQVY EEQAVYEPLE NEGIEITEVT APPEDNPVED SQVIVEEVSI 300 FPVEEQQEVP PETNRKTDDP EQKAKVKKKK PKLLNKFDKT IKAELDAAEK LRKRGKIEEA 360                       Peptide #H1<391 . . . 399> VNAFKELVRK YPQSPRARYG KAQCEDDLAE  KRRSNEVLR G AIETYQEVAS LPDVPADLLK 420   Peptide #H2<428 . . . 436>                  Peptide #H3<463 . . . 470> LSLKRRS DRQ QFLGHM RGSL LTLQRLVQLF PNDTSLKNDL GV GYLLIGDN DN AKKVYEEV 480 LSVTPNDGFA KVHYGFILKA QNKIAESIPY LKEGIESGDP GTDDGRFYFH LGDAMQRVGN 540             Peptide #H4<562569> KEAYKWYELG HKRGHFASVW Q RSLYNVNG L KAQPWWTPKE TGYTELVKSL ERNWKLIRDE 600  Peptide #H6<612 . . . 621> #H8<630 . . . 638> GLAVMDKAKG L FLPEDENLR E KGDWSQFT L WQQGRRNE NA CKGAPKTCTL LEKFPETTGC 660      Peptide #H7<676 . . . 685> RRGQIKYSIM HPGTH VWPHT GPTNC RLRMH LGLVIPKEGC KIRCANETKT WEEGKVLIFD 720                    Peptide #H5<749 . . . 758> DSFEHEVWQD ASSFRLIFIV DVWHPELT PQ QRRSLPAI                          758 // Sequence #SQ2: Locations of Peptides #C1-#C8 Along Canine ASPH, isoform X1 (794 aa) LOCUS XP_022267901 794 aa linear MAM 05 Sep. 2017 DEFINITION aspartyl/asparaginyl beta-hydroxylase isoform X1 [Canis lupus familiaris]. ACCESSION XP_022267901 VERSION XP_022267901.1 [. . . Text omitted . . .] ORIGIN   1 MAEETKHGGH KNGRKGGLSG SSFFTWFMVI ALLGVWTSVA VVWFDLVDYE EVLAKAKDFR   61 YNLSEVLQGK LGVYDADGDG DFDVDDAKVL LGLTKDGSNE NIDSLEEVLN ILAEESSDWF 121 YGFLSFLYDI MTPFEMLEEE EEESETADGV DGLKERSASK PTVPPEEAEP YPWLEEQVIE 181 DSGPQNTEDE VQEVQIESLL HEAVYTEHGD DVQQEEDGQV REPQPEDDFL VGSDTDDRYE 241 PLETGTFHEE TEDSYHIEET ASQAYNQDME EMMYEQDNPD SMEPIVGDDA RTYHEADDLT 301 YQDYDEPVYE PPENEGLESS DNAGEDSNII LEEVYMPPAE EQQEVPPETN RKTDDPEIKE 361 KVKKKKPKLL NKFDKTIKAE LDAAEKLRKR GKIEEALSAF QELVRKYPQS PRARYGKAQC Peptide #C1<427 . . . 435>              Peptide #C2<464 . . . 472> 421 EDDLAE KRRS NEVLR GAIET YQEVASLPNV PTDLLKLTLK RRS DRQQFLG HM RGSLITLQ             Peptide #C3<499 . . . 508> 481 KLVQLFPDDM SLKNDLGV GY LLIGDNNN AQ KVYEEVLNVT PNDGFAKVHY GFILKAQNKI                                                       Peptide #C4<598 541 AESIPYLKEG IESGDPGTDD GRFYFHLGDA MQRVGNKEAY KWYELGHKRG HFASVWQ RSL     .605>                                   Peptide #C6<648 . . . 657> 601  YNVHG LKAQP WWTPKETGYT ELVKSLERNW KLIRDEGLAV MDKAKGL FLP EDENLRE KGD        Peptide #C8<666 . . . 674>                            Peptide #C7<712 . . . 661 WSQFT LWQQG RKNE NACKGA PKTCSLLDKF PETTGCRRGQ IKYSIMHPGT H VWPHTGPTN .721> 721  C RLRMHLGLV IPKEGCKIRC ANETKTWEEG KVLIFDDSFE HEVWQDATSF RLIFIVDVWH     Peptide #C5<785 . . . 794> 781 PELT PQQRHS LPAI // Sequence #SQ3: Aligned Human ASPH (758 aa) and Canine ASPH, Isoform X1 (794 aa) Sequences Query IDXP_022267901.1 Description aspartyl/asparaginyl beta-hydroxylase isoform X1 [Canis lupus familiaris] Molecule type amino acid Query Length 794 Subject IDQ12797.3 Description RecName: Full= Aspartyl/asparaginyl beta-hydroxylase; AltName: Full = Aspartate beta-hydroxylase; Short = ASP beta-hydroxylase; AltName: Full = Peptide-aspartate beta-dioxygenase Molecule type amino acid Subject Length 758 Query   1 MAE-------------------------------ETKHGGHKNGRKGGLSGSSFFTWFMV  29     MA+                               ETKHGGHKNGRKGGLSG+SFFTWFMV Sbjct   1 MAQRKNAKSSGNSSSSGSGSGSTSAGSSSPGARRETKHGGHKNGRKGGLSGTSFFTWFMV  60 Query  30 IALLGVWTSVAVVWFDLVDYEEVLAKAKDFRYNLSEVLQGKLGVYDADGDGDFDVDDAKV  89     IALLGVWTSVAVVWFDLVDYEEVL               GKLG+YDADGDGDFDVDDAKV Sbjct  61 IALLGVWTSVAVVWFDLVDYEEVL---------------GKLGIYDADGDGDFDVDDAKV 105 Query  90 LLGLTKDGSNENIDSLEEVLNILAEESSDWFYGFLSFLYDIMTPFEMLEEEEEESETADG 149     LLGL Sbjct 106 LLGL-------------------------------------------------------- 109 Query 150 VDGLKERSASKPTVPPEEAEPYPWLEEQVIEDSGPQNTEDEVQEVQIESLLHEAVYTEH- 208         KERS S+P VPPEEAEP+   EEQV  ++ PQN EDE +E QI+SLLHE V+ EH Sbjct 110 ----KERSTSEPAVPPEEAEPHTEPEEQVPVEAEPQNIEDEAKE-QIQSLLHEMVHAEHV 164 Query 209 -GDDVQQEEDGQVREPQPEDD-FLVGSDTDDRYEPLETGTFHEETEDSYHIEETASQAYN 266      G+D+QQE DG   EPQ EDD FL+ +D DDR+E LE    HEETE SYH+EET SQ  N Sbjct 165 EGEDLQQE-DGPTGEPQQEDDEFLMATDVDDRFETLEPEVSHEETEHSYHVEETVSQDCN 223 Query 267 QDMEEMMYEQDNPDSMEPIVGDDARTYHEADDLTYQDYDEP-VYEPPENEGLESS----- 320     QDMEEMM EQ+NPDS EP+V +D R +H+ DD+TYQ Y+E  VYEP ENEG+E + Sbjct     QDMEEMMSEQENPDSSEPVV-EDERLHHDTDDVTYQVYEEQAVYEPLENEGIEITEVTAP Query 321 --DNAGEDSNIILEEVYMPPAEEQQEVPPETNRKTDDPEIKEKVKKKKPKLLNKFDKTIK 378       DN  EDS +I+EEV + P EEQQEVPPETNRKTDDPE K KVKKKKPKLLNKFDKTIK Sbjct 283 PEDNPVEDSQVIVEEVSIFPVEEQQEVPPETNRKTDDPEQKAKVKKKKPKLLNKFDKTIK 342                                          Peptide #C1<427 . . . 435> Query 379 AELDAAEKLRKRGKIEEALSAFQELVRKYPQSPRARYGKAQCEDDLAE KRRSNEVLR GAI 438     AELDAAEKLRKRGKIEEA++AF+ELVRKYPQSPRARYGKAQCEDDLAEKRRSNEVLRGAI Sbjct 343 AELDAAEKLRKRGKIEEAVNAFKELVRKYPQSPRARYGKAQCEDDLAE KRRSNEVLR GAI 402                                          Peptide #H1<391 . . . 399>                   Peptide #C2<464 . . . 472> Query 439 ETYQEVASLPNVPTDLLKLTLKRRS DRQQFLGHM RGSLITLQKLVQLFPDDMSLKNDLGV 498     ETYQEVASLP+VP DLLKL+LKRRSDRQQFLGHMRGSL+TLQ+LVQLFP+D SLKNDLGV Sbjct 403 ETYQEVASLPDVPADLLKLSLKRRS DRQQFLGHM RGSLLTLQRLVQLFPNDTSLKNDLGV 462                   Peptide #H2<428 . . . 436>  Peptide #C3<499 . . . 508> Query 499  GYLLIGDNNN AQKVYEEVLNVTPNDGFAKVHYGFILKAQNKIAESIPYLKEGIESGDPGT 558     GYLLIGDN + NA+KVYEEVL+VTPNDGFAKVHYGFILKAQNKIAESIPYLKEGIESGDPGT             * Sbjct 463  GYLLIGDNDN AKKVYEEVLSVTPNDGFAKVHYGFILKAQNKIAESIPYLKEGIESGDPGT 552  Peptide #H3<463 . . . 470>                                            Peptide #C4<598605> Query 559 DDGRFYFHLGDAMQRVGNKEAYKWYELGHKRGHFASVWQ RSLYNVHG LKAQPWWTPKETG 618     DDGRFYFHLGDAMQRVGNKEAYKWYELGHKRGHFASVWQRSLYNV + GLKAQPWWTPKETG Sbjct                                                  * 523 DDGRFYFHLGDAMQRVGNKEAYKWYELGHKRGHFASVWQ RSLYNVNG LKAQPWWTPKETG 582                                 Peptide #H4<562569>                       Peptide #C6<648 . . .    657>  #C8<666 . . . 674> Query 619 YTELVKSLERNWKLIRDEGLAVMDKAKGL FLPEDENLRE KGDWSQFT LWQQGRKNE NACK 678     YTELVKSLERNWKLIRDEGALVMDKAKGL FLPEDENLRE KGDWSQFT LWQQGR+NE NACK Sbjct                                                          * 583 YTELVKSLERNWKLIRDEGLAVMDKAKGLFLPEDENLREKGDWSQFTLWQQGRRNENACK 642                       Peptide #H6<612 . . .    621>  #H8<630 . . . 638>                           Peptide #C7<712 . . . 721> Query 679 GAPKTCSLLDKFPETTGCRRGQIKYSIMHPGTH VWPHTGPTNC RLRMHLGLVIPEKGCKI 738     GAPKTC+LL+KFPETTGCRRGQIKYSIMHPGTHVWPHTGPTNCRLRMHLVLVIPKEGCKI Sbjct 643 GAPKTCTLLEKFPETTGCRRGQIKYSIMHPGHT VWPHTGPTNC RLRMHLGLVIPKEGCKI 702                           Peptide #H7<676 . . . 685>                                        Peptide #C5<785 . . . 794> Query 739 RCANETKTWEEGKVLIFDDSFEHEVWQDATSFRLIFIVDVWHPELT PQQRHSLPAI  794     RCANETKTWEEGKVLIFDDSFEHEVWQDA+SFRLIFIVDVWHPELTPQQR_SLPAI Sbjct                                                       * 703 RCANETKTWEEGKVLIFDDSFEHEVWQDASSFRLIFIVDVWHPELT PQQRRSLPAI  758                                        Peptide #H5<749 . . . 758>

Example 1—Design and Synthesis of Synthetic Peptides Corresponding to Epitopes of ASPH Synthesis of Exemplary Compounds

Synthetic peptides derived from human and/or canine ASPH were designed that correspond to eight domain regions (#1-#8, as #H1-#H8 and #C1-#C8), as penultimate domain epitopes of the full length polypeptide, as illustrated in FIG. 2A, and shown in FIG. 2B and below in Table #T2. These peptides were rationally selected based upon the spatial distance from the substrate, as found in crystal structure 5JZZ deposited at the RCSB Protein Databank. Peptide epitope domain regions #1-#3 are from the non-catalytic domain, while peptide epitope domain regions #4 & #5 are from the C-terminal catalytic domain, but outside of residues 650-700. Peptide epitope domain regions #6, #7, and #8 are within or near the C-terminal catalytic domain of ASPH.

TABLE #T2 Peptide Sequences Corresponding to Penultimate Domain Epitopes of Human and Canine ASPH Epitope Short Positions in Positions in SEQ Domain Organism Sequence Name Human ASPH Canine ASPH ID NOS #1 HUMAN/CANINE KRRSNEVLR #H1/#C1 391-399 427-435 03/11 #2 HUMAN/CANINE DRQQFLGHM #H2/C2 428-536 464-472 04/12 #3 HUMAN GYLLIGDNDN #H3 463-470 05 CANINE GYLLIGDNNN #C3 499-508 13 #4 HUMAN RSLYNVNG #H4 562-569 06 CANINE RSLYNVHG #C4 598-605 14 #5 HUMAN PQQRRSLPAI #H5 749-758 07 CANINE PQQRHSLPAI #C5 785-794 15 #6 HUMAN/CANINE FLPEDENLRE #H6/C6 612-621 648-657 08/16 #7 HUMAN/CANINE VWPHTGPTNC #H7/C7 676-685 712-721 10 #8 HUMAN LWQQGRRNE #H8 630-638 10 CANINE LWQQGRKNE #C8 666-674 18

Example 2—Immunization of Peptide Candidates into Rabbits and Test Bleed

ImmunoPrecise Antibodies Ltd. (Victoria, British Columbia, Canada) carried out immunization of peptide candidates into rabbits, the testing of antibodies from rabbit B cells, cloning of variable regions into expression vectors, and DNA sequencing of selected rabbit MAbs (Examples 2-8) using standard procedures, under contract with principal investigators at Midwestern University (Glendale, Ariz.).

TABLE #T3 Synthetic Peptide Sequences Used as Immunogens Directed against ASPH Positions Short in Human Epitope SEQ Name Description/Sequence ASPH Domain ID NOS Peptide #1 Synthetic peptide comprising 29 amino acids 731-758 #5 19 (CASSF- with Cystein at its amino terminus, plus PO3H2) 28 amino acids corresponding to positions 731-758 at the C-terminal end of human ASPH, with the Threonine at 19 (corresponding to 748 of ASPH) phosphorylated. C-ASSFRLIFIV DVWHPEL-T(PO3H2)-PQ QRRSLPAI Peptide #2 Synthetic peptide comprising 29 amino acids 731-758 #5 20 with Cysteineat its amino terminus, plus 28 amino acids corresponding to positions 731-758 at the C-terminal end of human ASPH. C-ASSFRLIFIV DVWHPELTPQ QRRSLPAI

Synthetic peptides #1 and #2 (1 mg each) were prepared at a purity of >95%. The N-terminal Cysteine residue on each peptide is used to facilitate conjugation of each peptide to other molecules. BSA and KLH (2 mg each) were synthesized or obtained from commercial sources.

Peptide #1 (SEQ ID NO: 19) CASSFRLIFIVDVWHPEL-T(PO3H2)-PQQRRSLPAI Peptide #2 (SEQ ID NO: 20) CASSFRLIFIVDVWHPELTPQQRRSLPAI

Briefly, 3-6 mg of immunizing/screening antigen were prepared and stored in a neutral pH, sterile, buffered solution, at a minimum concentration of 0.5 mg/L. Antigen (hapten) was conjugated to an appropriate carrier and emulsified in Freund's Complete adjuvant, and used to immunize two New Zealand White (NZW) rabbits by subcutaneous injections. Booster injections of antigen in Freund's Incomplete adjuvant were carried at 3 week intervals. Blood samples (test bleeds) were collected 7-10 days after the second boost and immune sera were tested for specific antibody titer by ELISA. Each rabbit was given a final boost, if required, and whole blood was used to obtain B cells to generate Monoclonal Antibodies (MAbs) by the methods noted below.

Example 3—In Vitro Culture of Rabbit B Cells

Whole rabbit blood was collected after the final boost, and B cells were isolated, purified, and cultured by ImmunoPrecise Antibodies Ltd.

Example 4—Screening and Analysis of Antibodies from Rabbit B Cells

Screening was performed on the immunizing antigen by an indirect ELISA performed by ImmunoPrecise Antibodies Ltd.

ELISA plates were obtained from Costar Corning (Catalog #0720039). Blocking solutions included BSA (Bovine serum albumin) and Skim milk powder (MP). Phosphate buffered saline (PBS) at pH 7.4, PBS with 0.05% Tween-20 at pH 7.4, and Carbonate coating buffer (CCB) at pH 9.6 were used in the ELISA tests. Primary antibodies being tested included the immune sera, B cell supernatants, and transfected supernatants (recombinant rabbit MAbs). Secondary antibodies included Goat Anti-Rabbit IgG-Fc-HRP, Subisotype IgG1, obtained from Jackson ImmunoResearch (Catalog #111-035-046), and AffiniPure goat anti-rabbit IgG (H+L), Subisotype IgG1, obtained from Jackson ImmunoResearch (Catalog #111-035-144). Substrate reagents included TMB (3,3′,5,5′-tetramethyl-benzidine buffer), TMB One Component HRP Microwell Substrate, and BioFx cat #TMBW-1000-01.

Briefly, B cell culture supernatants from 96-well plates were transferred to ELISA plates coated with antigen. An indirect ELISA was performed by probing each well with a secondary antibody that binds to rabbit IgG antibodies. Wells with cells that tested positive were retested with the immunizing antigen to confirm specificity and binding.

Samples corresponding to the top responding wells were preserved in lysis buffer.

Cell culture supernatants from positive wells (in a volume of <50 μL) were also preserved.

Example 5—Cloning Antibody Heavy and Light Chain Variable Regions in Mammalian Expression Vectors

Cells from selected wells of B cells were amplified and samples of mRNA prepared from those cells by ImmunoPrecise Antibodies Ltd. Complementary DNAs corresponding to rabbit IgG heavy and kappa light chain variable regions were prepared and cloned separately into mammalian expression vectors comprising rabbit heavy and light chain constant regions, respectively.

Example 6—Expression of Antibody Heavy and Light Chain Variable Regions into HEK293 Cells

Two plasmids, one comprising a heavy chain variable and a constant region and one comprising a light chain variable and constant region, were co-transfected into HEK293 cells, and allowed to express both chains of the rabbit antibodies.

Example 7—Analysis of Cell Culture Supernatants

The cell culture supernatants were assayed for activity by indirect ELISA against the immunizing peptide (Peptide #1, SEQ ID NO: 13). Ten clones (#1-#10) having positive activity against immunizing peptide were identified. One clone produced an antibody that reacted with the phosphorylated Peptide #1, and four clones produced antibodies that reacted against both the phosphorylated Peptide #1 (SEQ ID NO: 19) and the non-phosphorylated Peptide #2 (SEQ ID NO: 20).

Example 8—DNA Sequencing of Heavy and Light Chain Regions from Selected Positive Rabbit MAbs

Ten clones were selected, five comprising heavy chains (1H2, 5H1, 5H3, 5H4 and 9H2), and five comprising kappa chains (1K6, 5K1, 5K3, 5K6 and 9K1). Purified plasmid DNA samples were prepared and sent to Macrogen USA for sequencing and analyzed by SnapGene Version 4.0.4.

The rabbit IgG heavy chain sequence is about 1200 bp in length, and can be sequenced from its 5′ end to obtain a reliable full-length variable sequence. The rabbit kappa light chain is about 700 bp in length, and full-length variable sequence can be reliably obtained from sequencing in the 5′ direction.

Analysis of Translation of Consensus Amino Acid Sequences

The nucleotide sequences of the variable regions of five heavy chains and five kappa chains were analyzed. Table #T4 discloses the translated variable regions encoded by the nucleotide sequences of the top 10 clones. Sequences highlighted in bold with a single underline (as GQPK) show the start of the constant region for heavy chains, and sequences highlighted in italic and double underline (as GDPV) show the start of the constant region of kappa chains.

TABLE #T4 Translated variable region sequences of the top clones SEQ # Clone ID Description or Sequence Length Type ID NO  1 1H2 METGLRWLLLVAVLKGVQCQSLEESGGDLVKPGASLTLTCTAS 150 AA 21 GLSFSDNFMCWVRQAPGKGLEWIACIYFDSSGITYYASWAKGR FTISKTSSPTVTLQMTSLTAADTATYFCARDGPGSISWDLWGQ GTLVTVSS GQPK APSVFPLAP  2 1K6 MDTRAPTQLLGLLLLWLPGATFAQVLTQTPSPVSAAVGGTVTI 148 AA 22 SCQSSKSVYSKNRLAWYQQKPGQPPKLLIYEASKLASGVPSRF KGSGSGTQFTLTISGVQCDDAATYYCQGTYDSSGWYWAFGGGT EVVVK

APTVLIFPPA  3 5H1 METGLRWLLLVAVLKGVQCQSLEESGGDLVKPGASLTLTCKAS 142 AA 23 GFDFSSNAMCWVRQAPGKGPEWIACIDNGDGSTDYATWAKGRF TISKTSSTTVTLQMTSLTAADTATYFCTRNFNLWGPGHPGHRL ERTAESPVGVSTG  4 5H3 METGLRWLLLVAVLKGVQCQSLEESGGDLVKPGASLTLTCKAS 143 AA 24 GFDFSSNAMCWVRQAPGKGPEWIACIDNGDGSTDYATWAKGRF TISKTSSTTVTLQMTSLTAADTATYFCTRNFNLWGQGTLVTVS S GQPK APSVFPLAP  5 5H4 METGLRWLLLVAVLKGVQCQSLEESGGDLVKPGASLTLTCKAS 143 AA 25 GFDFSSNAMCWVRQAPGKGPEWIACIDNGDGSTDYATWAKGRF TISKTSSTTVTLQMTSLTAADTATYFCTRNFNLWGQGTLVTVS S GQPK APSVFPLAP  6 5K1 MDTRAPTQLLGLLLLWLPGATFAQVLTQTASSVSAAVGGTVTI 146 AA 26 SCQSSQSVYDNNRLAWFQQKPGQPPKLLIYETSKLASGVPLRF KGSGSGTQFTLTISDLECDDAATYYCLGSYSGYIYTFGGGTEV VVK

APTVLIFPPA  7 5K3 MDTRAPTQLLGLLLLWLPGATFAQVLTQTASSVSAAVGGTVTI 146 AA 27 SCQSSQSVYDNNRLAWFQQKPGQPPKLLIYETSKLASGVPLRF KGSGSGTQFTLTISDLECDDAATYYCLGSYSGYIYTFGGGTEV VVK

APTVLIFPPA  8 5K6 MDTRAPTQLLGLLLLWLPGATFAQVLTQTASSVSAAVGGTVTI 146 AA 28 SCQSSQSVYDNNRLAWFQQKPGQPPKLLIYETSKLASGVPLRF KGSGSGTQFTLTISDLECDDAATYYCLGSYSGYIYTFGGGTEV VVK

APTVLIFPPA  9 9H2 METGLRWLLLVAVLKGVQCQSLEESGGDLVKPGASLTLTCKAS 142 AA 29 GFDFISNAMCWVRQAPGKGPEWIACIDNGDGSTDYATWAKGRF TISKTSSTTVTLQMTSLTAADTATYFCTRNFNLWGQGTL?TVS S GQPK APSVFPLAP 10 9K1 MDTRAPTQLLGLLLLWLPGATFAQVLTQTASSVSAAVGGTVTI 146 AA 30 SCQSSQSVYDNNRLAWFQQKSGQPPKLLIYETSKLASGVPLRF KGSGSGTQFTLTISDLECDDAATYYCLGSYSGYIYTFGGGTEV VVK

APTVLIFPPA

These results demonstrate that recombinant monoclonal antibodies derived from rabbits, were generated successfully against Peptide #1 (SEQ ID NO: 13). Recombinant Clones 5H1, 5H3, 5H4, and 9H2 have the same heavy chain sequences, and recombinant clones 5K1, 5K3 and 9K1 have the same kappa chain sequence.

Sequence #SQ4: Multiple Sequence Alignment of Heavy Chains for Clones 1H2, 5H1, 9H2, 5H3, and 5H4 A multiple sequence alignment of five clones comprising heavy chains illustrates slight  differences in the encoded polypeptide sequences in regions within and just flanking   CDR1, CDR2, CDR3,with notable divergence for sequences after CDR3 for clone 5H1. CLUSTAL O (1.2.4) multiple sequence alignment heavy chains:

The CDR1 regions from the heavy chain clones include the sequences NFMC (SEQ ID NO: 31), corresponding to residues 50-53 of SEQ ID NO: 21, and NAMC (SEQ ID NO: 32), corresponding to residues 50-53 of SEQ ID NOS: 23, 29, 24, and 25. The CDR2 regions from the heavy chain clones include CIYF (SEQ ID NO: 33) corresponding to residues 68-71 of SEQ ID NO: 21, and CIDN (SEQ ID NO: 34) corresponding to residues 68-71 of SEQ ID NO: 23, 29, 24, and 25. The CDR3 regions from the heavy chain clones include DGPGSISWDI (SEQ ID NO: 35) corresponding to residues 117-126 of SEQ ID NO: 21, and NFNI (SEQ ID NO: 36) corresponding to residues 116-119 of SEQ ID NOS: 23, 29, 24, and 25.

Sequence #SQ5: Multiple Sequence Alignment of Kappa Light Chains   for Clones 1K6, 5K1, 5K3, 5K6, and 9K1 A multiple sequence alignment of five clones comprising kappa light chains illustrates    slight differences in the encoded polypeptide sequences in regions within and just flanking   CDR1, CDR2, CDR3, with notable divergence for sequences within CDR3 for clone 1K6. CLUSTAL O (1.2.4) multiple sequence alignment kappa chains:

The CDR1 regions from the kappa chain clones 1K6, 5K1, 5K3, 5K6, and 9K1 include SVYSKNR (SEQ ID NO: 37) corresponding to residues 50-56 of SEQ ID NO: 22, and SVYDNNR (SEQ ID NO: 38) corresponding to residues 50-56 of SEQ ID NOS: 26, 27, 28, and 30. The CDR2 regions from the kappa chain clones were all LAS (SEQ ID NO: 39) corresponding to residues 78-80 of SEQ ID NOS: 22, 26, 27, 28, and 30. The CDR3 regions from the kappa chain clones included QGTYDSSGWYWA (SEQ ID NO: 40) corresponding to residues 113-124 of SEQ ID NO: 22, and LGSYSGYIYI (SEQ ID NO: 41) corresponding to residues 113-122 of SEQ ID NOS: 26, 27, 28, and 30.

Example 9—Analysis of MAbs by Immunohistochemistry (IHC)—Phase I—Antibody Triage

Antibody triage (Phase I) was performed by Reveal Biosciences (San Diego, Calif.) on a Leica Bond automated immunostainer, testing each antibody at 8 μg/mL, in parallel with a negative control performed in absence of primary antibody. FFPE human hepatocellular carcinoma was used for antibody testing.

Heat induced antigen retrieval was performed using Leica Bond Epitope Retrieval Buffer 1 (Citrate Buffer, pH6.0) and Leica Bond Epitope Retrieval Buffer 2 (EDTA solution, pH9.0) for 20 minutes (ER2(20)). Non-specific antibody binding was blocked using 3% Normal Goat Serum in PBST. Tests for positive reactions were carried out by using Novocastra Bond Refine Polymer Detection reagent, and visualized with 3′3-diaminobenzidine (DAB; brown). A Hematoxylin nuclear counterstain (blue) was also applied.

When Phase I optimization slides were evaluated, only two samples, 5H4/5K3 and 9H2/9K1, showed positive staining in Epitope Retrieval Buffer, ER2(20), as noted below.

TABLE #T5 Results of Antibody Triage Host Antigen Groups Antibody Dilution Species Retrieval 1 1H2/1K6 8 μg/mL Rabbit NONE 1H2/1K5 NONE 1H4/1K6 NONE 1H4/1K4 NONE 2 2H4/2K5 NONE 5H1/5K1 NONE 5H4/5K3 ER2(20) 9H2/9K1 ER2(20)

Two antibodies, 5H4/5K3 and 9H2/9K1, that showed positive staining in ER2(20), were selected for further testing in Phase II.

Example 10A—Analysis of MAbs by Immunohistochemistry (IHC)—Phase II—IHC Optimization

Immunohistochemistry (IHC) Optimization was performed by Reveal Biosciences (San Diego, Calif.) on a Leica Bond automated immunostainer, by testing each antibody at 2 μg/mL, 4 μg/mL, 8 μg/mL, and 10 μg/mL.

Heat induced antigen retrieval was performed using Leica Bond Epitope Retrieval Buffer 2 (EDTA solution, pH9.0) for 20 minutes (ER2(20)). Non-specific antibody binding was blocked using 3% Normal Goat Serum in PBST. Tests for positive reactions were carried out by using Novocastra Bond Refine Polymer Detection and visualized with 3′3-diaminobenzidine (DAB; brown). A Hematoxylin nuclear counterstain (blue) was applied.

When Phase II optimization samples were evaluated, no staining was observed at 2 μg/mL for 5H4/5K3 and 9H2/9K1. A strong signal was detected at both 8 μg/mL and 10 μg/mL for 5H4/5K3, as illustrated in FIG. 6. A strong signal was detected at both 8 μg/mL, and 10 μg/mL for 9H2/9K1, with a stronger intensity at 10 μg/mL, as illustrated in FIG. 7.

These results demonstrate that 5H4/5K3 and 9H2/9K1 are notable as leads for the development of diagnostic agents, and also as therapeutic drug products suitable for use in mammals, such as humans, by grafting the CDRs onto a suitable antibody framework that will facilitate the targeting of one or more drug products to cancerous tissues in a human subject.

Example 10B—Analysis of MAbs by Immunohistochemistry (IHC)—Phase III—IHC on Tissue Micro Arrays

Immunohistochemistry (IHC) was performed on a Leica Bond automated immunostainer using 5H4/5K3 at 8 μg/mL on TMAs (Table #T5).

Heat induced antigen retrieval was performed using Leica Bond Epitope Retrieval Buffer 2 (EDTA solution, pH9.0) for 20 minutes (ER2(20)). Non-specific antibody binding was blocked using 3% Normal Goat Serum in PBST.

Positivity was detected using Novocastra Bond Refine Polymer Detection and visualized with 3′3-diaminobenzidine (DAB; brown). A Hematoxylin nuclear counterstain (blue) was applied.

Isotype controls were performed on Human Hepatocellular carcinoma slide and each TMA type alongside their respective positive (with primary) slide using Rabbit IgG (Abcam ab172730, lot #GR3179509-3).

A human hepatocellular carcinoma FFPE block was sectioned at 4 um thickness and mounted onto positively charged slides for assay development.

TABLE #T6 Tissue Micro Arrays used for IHC staining in Phase III Array Name Tissue Type LV12 Liver cancer tissue array with progressive changes NT01 Normal Human Tissue PC02 Pancreatic cancer tissue array OV01 Ovary cancer tissue array OV03 Ovary cancer tissue array with progressive changes

FIG. 8 sets forth an illustration demonstrating 5H4/5K3 Phase III on TMAs for samples labeled as LV12 Core F4 (top panel), and LV12 Core F4-Isotype (bottom panel). Positive 5H4/5K3 staining was visualized with DAB (brown). Isotype negative control was performed with Rabbit IgG (right images). The scale bar represents 20 μm.

FIG. 9 sets forth an illustration demonstrating 5H4/5K3 Phase III on TMAs for samples labeled as PCO2 Core A6 (top panel), and PCO2 Core A6-Isotype (bottom panel).

FIG. 10 sets forth an illustration demonstrating 5H4/5K3 Phase III on TMAs for samples labeled as OV03 Core C5 (top panel), and OV03 Core C5-Isotype (bottom panel).

FIG. 11 sets forth an illustration demonstrating 5H4/5K3 Phase III on TMAs for samples labeled as OV01 Core D2 (top panel), and OV01 Core D2-Isotype (bottom panel).

These results demonstrate that antibody 5H4/5K3 stains a broad range of ovarian cancer samples, from granuloma to serous to endometrioid cancers. Malignant cancers stain intensely, while benign and normal ovarian tissue samples do not stain under these conditions.

These and similar antibodies, plus fragments or derivatives thereof, should be useful as a key reagent in a kit to diagnose the presence of cancer cells in wide variety of research and clinical samples.

These and similar antibodies, plus fragments or derivatives thereof, may also be useful in the development of pharmaceutical compositions comprising a therapeutic agent when the CDRs are grafted onto an appropriate framework suitable to produce a drug product suitable for mammals, particularly non-human primate and human subjects, and livestock, and domestic pets, including dogs and cats.

Example 10C—Analysis of MAbs by Immunohistochemistry (IHC)—Phase III—IHC on Tissue Micro Arrays

FIG. 12 sets forth an illustration demonstrating activity of 5H4/5K3 Against Granulosa Cell Tumor Samples (A11 and B11). Positive 5H4/5K3 staining was visualized with DAB (brown) against Granulosa Cell Tumor (top images, A11 and B11). Isotype negative control was performed with Rabbit IgG (bottom images, A11 and B11).

FIG. 13 sets forth an illustration demonstrating activity of 5H4/5K3 Against Serrous Cystadenocarcinoma Stage III Samples (C5 and D5).

FIG. 14 sets forth an illustration demonstrating activity of 5H4/5K3 Against Serrous Cystadenocarcinoma Stage III Samples (C8 and D8).

FIG. 15 sets forth an illustration demonstrating activity of 5H4/5K3 Against Endometrioid Adenocarcinoma Stage III Samples (E8 and F8).

FIG. 16 sets forth an illustration demonstrating reaction of 5H4/5K3 Against Normal Ovarian Tissue Samples (A1 and B1).

FIG. 17 sets forth an illustration demonstrating reaction of 5H4/5K3 Against Thecoma (Theca Cell) Tumor Tissue (A5 and B5).

These results confirm activity of the 5H4/5K3 antibody against a variety of cancerous tissue samples, and a lack of activity against cells in normal tissue samples.

Example 11—Interactions Between ASPH and Selected MAbs Captured Via Protein G

The interaction between ASPH and a set of 6 antibodies were characterized by Essai Sciences LLC (Stillwater, Okla.) on a SensiQ Pioneer SPR Platform. The COOH2 sensor chip, which contains a planar dextran surface, was used for target immobilization. The buffer system was 10 mM HEPES, pH 7.4, 150 mM NaCl, and 0.01% Tween-20.

All channels of a COOH2 sensor chip were activated with a five-minute injection of 40 mM EDC and 10 mM NHS. Protein G was then injected across channels 1 and 2. 1 M ethanolamine, pH 8.0 was then injected across all three channels. Approximately 1000 response units of Protein G were captured on both channels 1 and 2 (FIG. 18). For each antibody-ASPH interaction, the antibody was injected on channel 1, leaving channels 2 and 3 as a Protein G reference and empty channel reference, respectively. After antibody capture, ASPH was injected at a single concentration. Following injection of ASPH, all three channels were injected with 10 mM NaOH for one minute to regenerate the Protein G surface. This was done twice for each antibody, at each tested concentration of ASPH.

All experimental results shown are from fixed-concentration analyses of the interactions. Given material constraints, as well as the nature of the interacting molecules, immobilization of the antibodies, and fixed-concentration injection of ASPH was the most feasible experimental setup for this study.

The response curves for each tested concentration of ASPH against each captured antibody are displayed below. FIG. 19 is the mock sample, which demonstrates no visible binding. The remaining antibodies (FIGS. 20-25) display affinity for ASPH that range from ˜60 nM (9H2/9K3, FIG. 24) to 920 nM (2H4/2K5, FIG. 22). We tested the phospho-selective antibody, 8H1/8K1 (FIG. 25), and observed no binding, even at the highest tested analyte concentration. The kinetics values for each interaction are listed in Table #T7.

TABLE #T7 Kinetics values for interaction of ASPH with antibodies. Antibody ka (M⁻¹s⁻¹) kd (s⁻¹) K_(D) (M) Mock — — — 2H4/2K5 1.83 ± 1.681 ± 920 ± 0.04e3 0.002e−3 20 nM 5H1/5K1 2.035 ± 2.410 ± 118.4 ± 0.002e4 0.002e−3 0.2 nM 5H4/5K3 1.683 ± 2.426 ± 144.2 ± 0.002e4 0.002e−3 0.2 nM 9H2/9K1 1.879 ± 2.363 ± 125.7 ± 0.002e4 0.002e−3 0.2 nM 9H2/9K3 2.985 ± 1.848 ± 61.9 ± 0.004e4 0.003e−3 0.1 nM 8H1/8K1 — — —

The interaction of the ASPH protein with a set of antibodies captured via Protein G was studied. A range of affinities from ˜60 nM to ˜920 nM for the binding antibodies was observed. A mock sample, and a phospho-selective antibody were also tested. No observable binding to the protein for the mock sample or the phospho-selective antibody was noted.

Example 12—In Vitro Cell Proliferation Assay with Antibodies Against Epitopes of ASPH in Three Tumor Cell Lines

Experiments to determine the half maximal inhibitory concentration (IC₅₀) of the potency of samples comprising selected antibodies in different types of cultured tumor cells were carried out by Translational Drug Development LLC.

FIG. 26 shows graphs illustrating IC₅₀ curves for three samples tested in 4T1 Murine Breast Tumor cells (Panel A, 5H4/5K3; Panel B, 9H2/9K1; and Panel C, Mock Antibody).

FIG. 27 shows graphs illustrating IC₅₀ curves for three samples tested in MCF-7 Human ER+ Breast Tumor cells (Panel A, 5H4/5K3; Panel B, 9H2/9K1; and Panel C, Mock Antibody).

FIG. 28 shows graphs illustrating IC₅₀ curves for three samples tested in MV411 Human Mantle Cell Leukemia cells (Panel A, 5H4/5K3; Panel B, 9H2/9K1; and Panel C, Mock Antibody).

TABLE #T8 Summary of IC₅₀ Results* Mean IC₅₀ Mean IC₅₀ Mean IC₅₀ (μg/mL) (μg/mL) (μg/mL) Cell Line Tissue Type 5H4/5K3 9H2/9K1 Mock Antibody 4T1 Murine Breast 0.026 0.008 0.280 Tumor MCF-7 Human ER+ 0.024 0.002 0.426 Breast Tumor MV411 Human Mantle 0.098 0.007 0.313 Cell Leukemia *Mean IC values are calculated as the average of IC₅₀ values obtained from two trials, A and B, for each of 3 antibody experiments in 3 cell lines, as noted in Panels A-C of FIGS. 26 through 28.

These results demonstrate that the antibodies designated as 5H4/5K3 and 9H2/9K1 both affect the viability of three tumor cell lines being tested, with the Mab designated 9H2/9K1 being more potent than the Mab designated 5H4/5K3.

The antibody designated as 5H4/5K3 appears to be more selective for breast tumors 4T1 and MCF-7.

Example 13—Generation of Humanized Chimeric Monoclonal Antibodies Targeting at Least One Epitope in the Catalytic Domain of ASPH

Humanized versions of non-human antibodies are chimeric antibodies that a minimal amount of polypeptide domains comprising amino acid sequences derived from the non-human antibody. Typically, residues from the hypervariable region of a human antibody are replaced with hypervariable residues from the non-human antibody, that have the desired specificity, affinity, and/or capacity. Humanized versions can also be prepared from non-human species, such as mouse, rat, rabbit, non-human primates, and other vertebrate species. Other regions, comprising amino acid residues that may contribute to structural integrity of the human antibody (framework region) may also be replaced by amino acid residues from the corresponding non-human residues. The humanized chimeric monoclonal antibodies may also comprise amino acid residues that are not found in the recipient human antibody or the non-human donor antibody. Generally, the humanized antibody comprises at least one, and preferably all of the variable domains of the donor antibody, and substantially all of the framework regions of the human antibody.

Variants may also comprise one or more portions of the constant region of an antibody, typically, a human antibody. Other types of variants, include fragments, and variants comprising one or more conservative substitutions, insertions, or deletions, that do not substantially alter the specificity, affinity, and/or capacity of the variant molecule compared to its parent molecule, but may offer additional advantages in terms of ease of production or purification, ability to be conjugated to other chemical moieties, which may facilitate covalent or non-covalent binding to other molecules comprising polypeptide domains or other reactive or non-reactive moieties, capable of providing a secondary reporter function, such as emission of fluorescent light, or conversion of a colorless substrate to an easily detectable, colored product, which may be useful as components in diagnostic kits for use in research and in clinical settings. Aspects of the invention also include variants that are >80%, >85%, >90%, >91%, >92%, >93%, >94%, >95%, >96%, >98%, >99%, or >99.5% identical to at least one of the variable regions of the donor antibody.

In the examples noted above, recombinant monoclonal antibodies were generated against Peptide #1 (SEQ ID NO: 13). Recombinant Clones 5H1, 5H3, 5H4, and 9H2 have the same heavy chain sequences, and recombinant clones 5K1, 5K3 and 9K1 have the same kappa chain sequence. The CDR1 regions from the heavy chain clones include the sequences NFMC (SEQ ID NO: 31) and NAMC (SEQ ID NO: 32). The CDR2 regions from the heavy chain clones include CIYF (SEQ ID NO: 33) and CIDN (SEQ ID NO: 34). The CDR3 regions from the heavy chain clones include DGPGSISWDI (SEQ ID NO: 35) and NFNI (SEQ ID NO: 36). The CDR1 regions from the kappa chain clones include SVYSKNR (SEQ ID NO: 37) and SVYDNNR(SEQ ID NO: 38). The CDR2 regions from the kappa chain clones were all LAS (SEQ ID NO: 39). The CDR3 regions from the kappa chain clones included QGTYDSSGWYWA (SEQ ID NO: 40) and LGSYSGYIYI (SEQ ID NO: 41).

Plasmids comprising cDNAs encoding rabbit antibodies targeting epitopes of ASPH described in Examples 5-8 are used as a source of nucleic acids comprising variable regions to generate humanized monoclonal antibodies that target at least one epitope in the catalytic domain of ASPH. One or more codons within the rabbit cDNAs may be altered to represent codons that are optimally used in the host cell expression system, to enhance expression of the encoded chimeric polypeptide under the control of operably-linked promoters and other genetic elements. Random and targeted mutagenesis of specific residues within the variable regions may result in antibodies that have increased affinity to its intended target, and/or reduced affinity to other targets.

Example 14—Generation of Bispecific Antibodies Targeting at Least One Epitope in the Catalytic Domain of ASPH

Bispecific antibodies combine the structural domains of two distinct molecules into one molecule with the goal of preserving and perhaps enhancing functional properties of the chimeric molecule compared to its parent mono-specific molecules (Dahlen E. et al, Bispecific antibodies in cancer immunotherapy. Therapeutic Advances in Vaccines and Immunotherapy, 2018, 6:(1)3-17). In some cases, bispecific antibodies have superior therapeutic properties compared to compositions comprising mixtures of monospecific compounds.

Several classes of immunotherapeutic bispecific antibodies have been recognized, including T-cell redirectors, which act on malignant cells by targeting a tumor antigen and CD3; NK-cell redirectors, which act on malignant cells targeting a tumor antigen and CD16A; Tumor-targeted immunomodulators, which direct co-stimulation of tumor-infiltrating immune cells by targeting a tumor antigen and co-stimulatory molecules, such as CD40 or 4-1BB; and Dual immunomodulators, which simultaneously act on two immunomodulatory targets, resulting in blockade of inhibitory targets, depletion of suppressive cells, or activation of effector cells (See Table 1 of Dahlen et al).

A non-limiting list of exemplary tumor antigens includes CD19, EpCAM, CD20, CD23, BCMA, B7H3, and PSMA.

A non-limiting list of T-cell specific epitopes includes CD3, CD3e, OX40, CD27, ICOS and GITR.

A non-limiting list of co-stimulatory molecules includes CD40 and 4-1BB.

A non-limiting list of immunomodulating targets includes PD-L1, CTLA-4, TGF-β, LAG-2, TIM-3, and OX40.

Bispecific antibodies comprising at least one complementarity-determining region (CDR) targeting one or more epitopes of ASPH selected from the group consisting of CDR1, CDR2, and CDR3 from the heavy chain or the light chain clones of Example 13 are prepared by fusing rabbit, other non-human, human, or humanized antibodies comprising these regions with an antibody targeting one or more tumor antigens, T-cell specific epitopes, co-stimulatory molecules, or immunomodulating targets, as noted above.

Exemplary bi-specific antibodies include a molecule comprising the CDRs of the 5H4/5K3 antibody disclosed herein, where the 5H4 CDR1=NAMC (SEQ ID NO: 31), CDR2=CIDN (SEQ ID NO: 34), and CDR3=NFNI (SEQ ID NO: 36), and where the 5K3 CDR1=SVYDNNR (SEQ ID NO: 38)), CDR2=LAS (SEQ ID NO: 39), CDR3=LGSYSGYIYI (SEQ ID NO: 41) or 9H2/9K1 antibody, where the 9H2 CDR1=NAMC (SEQ ID NO: 32), CDR2=CIDN (SEQ ID NO: 34), and CDR3=NFNI (SEQ ID NO: 36), and the 9K1 CDR1=SVYDNNR (SEQ ID NO: 38), CDR2=LAS (SEQ ID NO: 39), and CDR3=LGSYSGYIYI (SEQ ID NO: 41), combined with an antibody molecule comprising one or more tumor antigens, T-cell specific epitopes, co-stimulatory molecules, or immunomodulating targets, as noted above.

An exemplary bispecific antibody of the T-cell redirector class includes an antibody targeting one or more ASPH CDRs with an antibody targeting CD3.

An exemplary bispecific antibody of the NK-cell redirector class includes an antibody targeting one or more ASPH CDRs with an antibody targeting CD16A.

An exemplary bispecific antibody of the tumor targeting immunomodular class includes an antibody targeting one or more ASPH CDRs with an antibody targeting CD40 or 4-1BB.

An exemplary bispecific antibody of the dual immunomodular class includes an antibody targeting one or more ASPH CDRs with an antibody targeting PD-L1, PD-1, CTLA-4, TGF-β, LAG-3, TIM-3, or OX40.

Statement Regarding Preferred Aspects are Meant to be Illustrative and not Limiting as to the Scope of the Invention

While the preferred aspects of the invention have been illustrated and described in detail, it will be appreciated by those skilled in the art that that various changes can be made therein without departing from the spirit and scope of the invention. Accordingly, the particular arrangements disclosed are meant to be illustrative only and not limiting as to the scope of the invention, which is to be given the full breadth of the appended claims and any equivalent thereof.

BIBLIOGRAPHY Statement Regarding Incorporation by Reference of Journal Articles and Patent Documents

All references, patents, or applications cited herein are incorporated by reference in their entirety, as if written herein.

Journal Articles

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Wands (2006). “Aspartyl-asparagyl     beta hydroxylase over-expression in human hepatoma is linked to     activation of insulin-like growth factor and notch signaling     mechanisms.” Hepatology 44(2): 446-457. -   Dinchuk, J. E., R. J. Focht, J. A. Kelley, N. L. Henderson, N. I.     Zolotarjova, R. Wynn, N. T. Neff, J. Link, R. M. Huber, T. C.     Burn, M. J. Rupar, M. R. Cunningham, B. H. Selling, J. Ma, A. A.     Stern, G. F. Hollis, R. B. Stein and P. A. Friedman (2002). “Absence     of post-translational aspartyl beta-hydroxylation of epidermal     growth factor domains in mice leads to developmental defects and an     increased incidence of intestinal neoplasia.” J Biol Chem 277(15):     12970-12977. -   Drakenberg, T., P. Fernlund, P. Roepstorff and J. Stenflo (1983).     “beta-Hydroxyaspartic acid in vitamin K-dependent protein C.” Proc     Natl Acad Sci USA 80(7): 1802-1806. -   El Asmar, Z., J. Terrand, M. Jenty, L. Host, M. Mlih, A. Zerr, H.     Justiniano, R. L. Matz, C. Boudier, E. Scholler, J. M. Garnier, D.     Bertaccini, D. Thierse, C. Schaeffer, A. Van Dorsselaer, J. Herz, V.     Bruban and P. Boucher (2016). “Convergent Signaling Pathways     Controlled by LRP1 (Receptor-related Protein 1) Cytoplasmic and     Extracellular Domains Limit Cellular Cholesterol Accumulation.” J     Biol Chem 291(10): 5116-5127. -   Furler, R. L., D. F. Nixon, C. A. Brantner, A. Popratiloff and C. H.     Uittenbogaart (2018). “TGF-beta Sustains Tumor Progression through     Biochemical and Mechanical Signal Transduction.” Cancers (Basel)     10(6). Gundogan, F., G. Elwood, D. Greco, L. P. Rubin, H.     Pinar, R. I. Carlson, J. R. Wands and S. M. de la Monte (2007).     “Role of aspartyl-(asparaginyl) beta-hydroxylase in placental     implantation: Relevance to early pregnancy loss.” Hum Pathol 38(1):     50-59. -   Iwagami, Y., S. Casulli, K. Nagaoka, M. Kim, R. I. Carlson, K.     Ogawa, M. S. Lebowitz, S. Fuller, B. Biswas, S. Stewart, X. Dong, H.     Ghanbari and J. R. Wands (2017). “Lambda phage-based vaccine induces     antitumor immunity in hepatocellular carcinoma.” Heliyon 3(9):     e00407. -   Lavaissiere, L., S. Jia, M. Nishiyama, S. de la Monte, A. M.     Stern, J. R. Wands and P. A. Friedman (1996). “Overexpression of     human aspartyl(asparaginyl)beta-hydroxylase in hepatocellular     carcinoma and cholangiocarcinoma.” J Clin Invest 98(6): 1313-1323. -   Noda, T., M. Shimoda, V. Ortiz, A. E. Sirica and J. R. Wands (2012).     “Immunization with aspartate-beta-hydroxylase-loaded dendritic cells     produces antitumor effects in a rat model of intrahepatic     cholangiocarcinoma.” Hepatology 55(1): 86-97. -   Revskaya, E., Z. Jiang, A. Morgenstern, F. Bruchertseifer, M.     Sesay, S. Walker, S. Fuller, M. S. Lebowitz, C. Gravekamp, H. A.     Ghanbari and E. Dadachova (2017). “A Radiolabeled Fully Human     Antibody to Human Aspartyl (Asparaginyl) beta-Hydroxylase Is a     Promising Agent for Imaging and Therapy of Metastatic Breast     Cancer.” Cancer Biother Radiopharm 32(2): 57-65. -   Tong, M., J. S. Gao, D. Borgas and S. M. de la Monte (2013).     “Phosphorylation Modulates Aspartyl-(Asparaginyl)-beta Hydroxylase     Protein Expression, Catalytic Activity and Migration in Human     Immature Neuronal Cerebellar Cells.” Cell Biol (Henderson, Nev.)     6(2). -   Wu, G., Z. Ma, Y. Cheng, W. Hu, C. Deng, S. Jiang, T. Li, F. Chen     and Y. Yang (2018). “Targeting Gas6/TAM in cancer cells and tumor     microenvironment.” Mol Cancer 17(1): 20. -   Yang, H., K. Song, T. Xue, X. P. Xue, T. Huyan, W. Wang and H. Wang     (2010). “The distribution and expression profiles of human     Aspartyl/Asparaginyl beta-hydroxylase in tumor cell lines and human     tissues.” Oncol Rep 24(5): 1257-1264. -   Yeung, Y. A., A. H. Finney, I. A. Koyrakh, M. S. Lebowitz, H. A.     Ghanbari, J. R. Wands and K. D. Wittrup (2007). “Isolation and     characterization of human antibodies targeting human aspartyl     (asparaginyl) beta-hydroxylase.” Hum Antibodies 16(3-4): 163-176. -   PDB ID 5JZZ: McDonough, M. A., Pfeffer, I., Munzel, M. (2016)     Aspartyl/Asparaginyl beta-hydroxylase (AspH)oxygenase and TPR     domains in complex with manganese, N-oxalylglycine and cyclic     peptide substrate mimic of factor X. DOI: 10.2210/pdb5JZZ/pdb.     Deposited as PDB ID 5JZZ on 2016 May 16, Released on 2017 Jun. 6;     Replaced by PDB ID 6RK9 on 2019 May 7. -   Dahlen E., Veltonmaki, and Norten, P. (2018) Bispecific antibodies     in cancer immunotherapy. Therapeutic Advances in Vaccines and     Immunotherapy 6(1): 3-17. 

What is claimed is:
 1. A method of treating cancer in a mammalian subject, comprising administering to a subject in need thereof a composition comprising an antibody or fragment or variant thereof, which binds to one or more peptide epitopes of human aspartyl (asparaginyl) β-hydroxylase (ASPH) in an amount sufficient to treat cancer, wherein said antibody comprises: a recombinant heavy chain and a recombinant light chain, each heavy and each light chain comprising 3 complementarity-determining regions (CDRs), or fragment or variant thereof, which binds to one or more peptide epitopes of human aspartyl (asparaginyl) β-hydroxylase (ASPH), wherein at least one of said peptide epitopes comprises at least 4 consecutive amino acid residues located within or adjacent to a position in the catalytic domain of ASPH that is within 30 amino acids of the C-terminus of human ASPH, corresponding to the sequence QDASSFRLIFIVDVWHPELTPQQRRSLPAI represented by positions 729-758 of SEQ ID NO: 1; wherein said antibody or fragment or variant thereof contains one or more conservative amino acid substitutions in which the functional activity relating to binding of the antibody or fragment thereof to an epitope of ASPH is retained; wherein said antibody comprises a recombinant heavy chain comprising a CDR1 comprising a sequence selected from the group consisting of NFMC represented by SEQ ID NO: 31, and NAMC represented by SEQ ID NO: 32; a CDR2 comprising a sequence selected from the group consisting of CIYF represented by SEQ ID NO: 33, and CIDN represented by SEQ ID NO: 34; and a CDR3 comprising a sequence selected from the group consisting of DGPGSISWKI represented by SEQ ID NO: 35, and NFNI represented by SEQ ID NO: 36; wherein said antibody comprises a recombinant light chain comprising a CDR1 comprising a sequence selected from the group consisting of SVYSKNR represented by SEQ ID NO: 37, and SVYDNNR represented by SEQ ID NO: 38; a CDR2 comprising the sequence LAS represented by SEQ ID NO: 39; and a CDR3 comprising a sequence selected from the group consisting of QGTYDSSGWYWA represented by SEQ ID NO: 40, and LGSYSGYIYI represented by SEQ ID NO:
 41. 2. The method of claim 1, wherein said antibody or fragment or variant binds to one or more peptides selected from the group consisting of (a) a peptide comprising 29 amino acids with Cysteine at its amino terminus, plus 28 amino acids corresponding to positions 731-758 at the C-terminal end of human ASPH represented by SEQ ID NO: 1, with the Threonine at relative position 19, corresponding to position 748 of human ASPH, phosphorylated, as CASSFRLIFIVDVWHPEL-T(PO₃H₂)-PQQRRSLPAI represented by SEQ ID NO: 19; and (b) a peptide comprising 29 amino acids with Cysteine at its amino terminus, plus 28 amino acids corresponding to positions 731-758 at the C-terminal end of human ASPH represented by SEQ ID NO: 1, as CASSFRLIFIVDVWHPELTPQQRRSLPAI, represented by SEQ ID NO:
 20. 3. The method of claim 1, wherein said antibody comprising a recombinant heavy chain and a recombinant light chain, or a fragment thereof, which binds to one or more peptide epitopes of human aspartyl (asparaginyl) β-hydroxylase (ASPH), wherein at least one of said peptide epitopes is located within or adjacent to a position in the catalytic domain of ASPH that is within 30 amino acids of the C-terminus of human ASPH, corresponding to the sequence QDASSFRLIFIVDVWHPELTPQQRRSLPAI represented by positions 729-758 of SEQ ID NO: 1; wherein said antibody binds to an epitope comprising at least 4 consecutive amino acid residues located within 30 amino acids from the C-terminal end of human ASPH represented by SEQ ID NO: 1; wherein said epitope comprising at least 4 consecutive amino acid residues located within 30 amino acids from the C-terminal end of human ASPH comprises the consecutive amino acid residues selected from the group consisting of PELT represented by SEQ ID NO: 42, ELTP represented by SEQ ID NO: 43, LTPQ represented by SEQ ID NO: 44, TPQQ represented by SEQ ID NO: 45, PQQR represented by SEQ ID NO: 46, QQRR represented by SEQ ID NO: 47, QRRS represented by SEQ ID NO: 48, RRSL represented by SEQ ID NO: 49, RSLP represented by SEQ ID NO: 50, SLPA represented by SEQ ID NO: 51, and LPAI represented by SEQ ID NO:
 52. 4. The method of claim 3, wherein said peptide epitope comprises a phosphorylated threonine, T(PO₃H₂) at relative amino acid position 4 of PELT represented by SEQ ID NO: 42; at relative amino acid position 3 of ELTP represented by SEQ ID NO: 43; at relative amino acid position 2 of LTPQ represented by SEQ ID NO: 44; and at relative amino acid position 1 of TPQQ represented by SEQ ID NO:
 45. 5. A method of treating cancer in a mammalian subject comprising administering to a subject in need thereof a composition comprising a monoclonal antibody comprising a recombinant heavy chain and a recombinant light chain, or a fragment thereof, which binds to one or more peptide epitopes of human aspartyl (asparaginyl) β-hydroxylase (ASPH), wherein at least one of said peptide epitopes is located within or adjacent to a position in the catalytic domain of ASPH that is within 30 amino acids of the C-terminus of human ASPH, corresponding to the sequence QDASSFRLIFIVDVWHPELTPQQRRSLPAI represented by positions 729-758 of SEQ ID NO: 1; wherein said antibody binds to an epitope comprising at least 4 consecutive amino acid residues located within 30 amino acids from the C-terminal end of human ASPH represented by SEQ ID NO: 1; wherein said antibody comprises a recombinant heavy chain and a recombinant light chain, wherein said recombinant heavy chain comprises a polypeptide sequence selected from the group consisting of SEQ ID NOS 21-25; and wherein said recombinant light chain comprises a polypeptide sequence selected from the group consisting of SEQ ID NOS 26-30.
 6. The method of claim 5, wherein said antibody is selected from the group consisting of 5H4/5K3 and 9H2/9K1, wherein antibody 5H4/5K3 comprises a heavy chain designated 5H4, represented by the sequence SEQ ID NO: 25, and a light chain 5K3, represented by the sequence SEQ ID NO: 27; and wherein antibody 9H2/9K1 comprises a heavy chain designated 9H2, represented by the sequence SEQ ID NO: 29, and a light chain 9K1 represented by the sequence SEQ ID NO:
 30. 7. The method of claim 1, wherein said mammalian subject is a selected from the group consisting of a human, non-human primate, canine, feline, bovine, equine, and a porcine subject.
 8. The method of claim 2, wherein said mammalian subject is a human subject.
 9. The method of claim 1, wherein said cancer is selected from the group consisting of cancers of the liver, hepatocellular carcinoma and cholangiocarcinoma, pancreatic cancer, gastric cancer, colon cancer, kidney cancer, non-small cell lung cancer, breast cancer, ovarian cancer, cervical cancer, head-and-neck cancers secondary to human papilloma virus infection, prostate cancer, brain cancer, glioblastoma multiform, neuroblastoma, retinoblastoma, and medulloblastoma, and osteosarcoma.
 10. The method of claim 1, wherein said antibody or fragment or variant thereof is humanized and comprises one or more complementarity determining regions (CDRs) derived from a non-human source, and one or more portions of the constant regions of a human antibody.
 11. The method of claim 1, wherein said antibody or fragment or variant thereof is bispecific and comprises one or more complementarity determining regions (CDRs) derived from a non-human source targeting one or more peptide epitopes located within or adjacent to the catalytic domain of ASPH, and an antibody targeting other epitopes selected from the group consisting of the T-cell redirector class, comprising an antibody targeting one or more ASPH CDRs and an antibody targeting CD3; the NK-cell redirector class, comprising an antibody targeting one or more ASPH CDRs and an antibody targeting CD16A; the tumor targeting immunomodular class, comprising an antibody targeting one or more ASPH CDRs and an antibody targeting CD40 or 4-1BB; and the dual immunomodular class, comprising an antibody targeting one or more ASPH CDRs and an antibody targeting PD-L1, PD-1, CTLA-4, TGF-β, LAG-3, TIM-3, or OX40.
 12. A method of inhibiting the proliferation of tumor cell or tissue samples grown in culture, comprising administering to the locus of the tumor cells a composition comprising an antibody or fragment or variant thereof which binds to one or more peptide epitopes of human aspartyl (asparaginyl) β-hydroxylase (ASPH) in an amount sufficient to inhibit proliferation, wherein said antibody comprises a recombinant heavy chain and a recombinant light chain, each heavy and each light chain comprising 3 complementarity-determining regions (CDRs), or fragment or variant thereof, which binds to one or more peptide epitopes of human aspartyl (asparaginyl) β-hydroxylase (ASPH), wherein at least one of said peptide epitopes comprises at least 4 consecutive amino acid residues located within or adjacent to a position in the catalytic domain of ASPH that is within 30 amino acids of the C-terminus of human ASPH, corresponding to the sequence QDASSFRLIFIVDVWHPELTPQQRRSLPAI represented by positions 729-758 of SEQ ID NO: 1; wherein said antibody or fragment or variant thereof contains one or more conservative amino acid substitutions in which the functional activity relating to binding of the antibody or fragment thereof to an epitope of ASPH is retained; wherein said antibody comprises a recombinant heavy chain comprising a CDR1 comprising a sequence selected from the group consisting of NFMC represented by SEQ ID NO: 31, and NAMC represented by SEQ ID NO: 32; a CDR2 comprising a sequence selected from the group consisting of CIYF represented by SEQ ID NO: 33, and CIDN represented by SEQ ID NO: 34; and a CDR3 comprising a sequence selected from the group consisting of DGPGSISWKI represented by SEQ ID NO: 35, and NFNI represented by SEQ ID NO: 36; wherein said antibody comprises a recombinant light chain comprising a CDR1 comprising a sequence selected from the group consisting of SVYSKNR represented by SEQ ID NO: 37, and SVYDNNR represented by SEQ ID NO: 38; a CDR2 comprising the sequence LAS represented by SEQ ID NO: 39; and a CDR3 comprising a sequence selected from the group consisting of QGTYDSSGWYWA represented by SEQ ID NO: 40, and LGSYSGYIYI represented by SEQ ID NO:
 41. 13. The method of claim 12, comprising inhibiting the proliferation of isolated tumor cells in tissue samples grown in culture. 